#include "BigInteger.hh"
-// MANAGEMENT
-
-// Assignment operator
void BigInteger::operator =(const BigInteger &x) {
// Calls like a = a have no effect
if (this == &x)
// Copy sign
sign = x.sign;
// Copy the rest
- BigUnsigned::operator =(x);
+ mag = x.mag;
}
-// Constructor from an array of blocks and a sign
-BigInteger::BigInteger(const Blk *b, Index l, Sign s) : BigUnsigned(b, l) {
+BigInteger::BigInteger(const Blk *b, Index blen, Sign s) : mag(b, blen) {
switch (s) {
- case zero:
- case positive:
- case negative:
- sign = (len == 0) ? zero : s;
+ case zero:
+ case positive:
+ case negative:
+ sign = mag.isZero() ? zero : s;
break;
- default:
- throw "BigInteger::BigInteger(Blk *, Index, Sign): Invalid sign";
+ default:
+ throw "BigInteger::BigInteger(const Blk *, Index, Sign): Invalid sign";
}
}
-// Constructor from a BigUnsigned and a sign
-BigInteger::BigInteger(const BigUnsigned &x, Sign s) : BigUnsigned(x) {
+BigInteger::BigInteger(const BigUnsigned &x, Sign s) : mag(x) {
switch (s) {
- case zero:
- case positive:
- case negative:
- sign = (len == 0) ? zero : s;
+ case zero:
+ case positive:
+ case negative:
+ sign = mag.isZero() ? zero : s;
break;
- default:
+ default:
throw "BigInteger::BigInteger(Blk *, Index, Sign): Invalid sign";
}
}
-/*
- * The steps for construction of a BigInteger
- * from an integral value x are as follows:
- * 1. If x is zero, create an empty BigInteger and stop.
- * 2. Allocate a one-block number array.
- * 3. If x is positive (or of an unsigned type), set the
- * sign of the BigInteger to positive.
- * 4. If x is of a signed type and is negative, set the
- * sign of the BigInteger to negative.
- * 5. If x is of a signed type, convert x (or -x if x < 0)
- * to the unsigned type of the same length.
- * 6. Expand x (or the result of step 5) to a Blk,
- * and store it in the number array.
- *
- * See remarks in `BigUnsigned.cc' and `NumberlikeArray.hh'
- * about new handling of zero-length arrays.
- */
+/* CONSTRUCTION FROM PRIMITIVE INTEGERS
+ * Same idea as in BigUnsigned.cc, except that negative input results in a
+ * negative BigInteger instead of an exception. */
-BigInteger::BigInteger(unsigned long x) {
- if (x == 0)
- sign = zero; // NumberlikeArray did the rest
- else {
- cap = 1;
- blk = new Blk[1];
- sign = positive;
- len = 1;
- blk[0] = Blk(x);
- }
+// Done longhand to let us use initialization.
+BigInteger::BigInteger(unsigned long x) : mag(x) {
+ sign = mag.isZero() ? zero : positive;
}
-
-BigInteger::BigInteger(long x) {
- if (x > 0) {
- cap = 1;
- blk = new Blk[1];
- sign = positive;
- len = 1;
- blk[0] = Blk(x);
- } else if (x < 0) {
- cap = 1;
- blk = new Blk[1];
- sign = negative;
- len = 1;
- blk[0] = Blk(-x);
- } else
- sign = zero;
+BigInteger::BigInteger(unsigned int x) : mag(x) {
+ sign = mag.isZero() ? zero : positive;
}
-
-BigInteger::BigInteger(unsigned int x) {
- if (x == 0)
- sign = zero;
- else {
- cap = 1;
- blk = new Blk[1];
- sign = positive;
- len = 1;
- blk[0] = Blk(x);
- }
+BigInteger::BigInteger(unsigned short x) : mag(x) {
+ sign = mag.isZero() ? zero : positive;
}
-BigInteger::BigInteger(int x) {
- if (x > 0) {
- cap = 1;
- blk = new Blk[1];
- sign = positive;
- len = 1;
- blk[0] = Blk(x);
- } else if (x < 0) {
- cap = 1;
- blk = new Blk[1];
- sign = negative;
- len = 1;
- blk[0] = Blk(-x);
- } else
- sign = zero;
-}
+// For signed input, determine the desired magnitude and sign separately.
-BigInteger::BigInteger(unsigned short x) {
- if (x == 0)
- sign = zero;
- else {
- cap = 1;
- blk = new Blk[1];
- sign = positive;
- len = 1;
- blk[0] = Blk(x);
+namespace {
+ template <class X, class UX>
+ BigInteger::Blk magOf(X x) {
+ /* UX(...) cast needed to stop short(-2^15), which negates to
+ * itself, from sign-extending in the conversion to Blk. */
+ return BigInteger::Blk(x < 0 ? UX(-x) : x);
+ }
+ template <class X>
+ BigInteger::Sign signOf(X x) {
+ return (x == 0) ? BigInteger::zero
+ : (x > 0) ? BigInteger::positive
+ : BigInteger::negative;
}
}
-BigInteger::BigInteger(short x) {
- if (x > 0) {
- cap = 1;
- blk = new Blk[1];
- sign = positive;
- len = 1;
- blk[0] = Blk(x);
- } else if (x < 0) {
- cap = 1;
- blk = new Blk[1];
- sign = negative;
- len = 1;
- blk[0] = Blk(-x);
- } else
- sign = zero;
+BigInteger::BigInteger(long x) : sign(signOf(x)),
+ mag(magOf<long, unsigned long>(x)) {}
+BigInteger::BigInteger(int x) : sign(signOf(x)),
+ mag(magOf<int, unsigned int>(x)) {}
+BigInteger::BigInteger(short x) : sign(signOf(x)),
+ mag(magOf<short, unsigned short>(x)) {}
+
+// CONVERSION TO PRIMITIVE INTEGERS
+
+/* Reuse BigUnsigned's conversion to an unsigned primitive integer.
+ * The friend is a separate function rather than
+ * BigInteger::convertToUnsignedPrimitive to avoid requiring BigUnsigned to
+ * declare BigInteger. */
+template <class X>
+inline X convertBigUnsignedToPrimitiveAccess(const BigUnsigned &a) {
+ return a.convertToPrimitive<X>();
}
-// CONVERTERS
-/*
- * The steps for conversion of a BigInteger to an
- * integral type are as follows:
- * 1. If the BigInteger is zero, return zero.
- * 2. If the BigInteger is positive:
- * 3. If it is more than one block long or its lowest
- * block has bits set out of the range of the target
- * type, throw an exception.
- * 4. Otherwise, convert the lowest block to the
- * target type and return it.
- * 5. If the BigInteger is negative:
- * 6. If the target type is unsigned, throw an exception.
- * 7. If it is more than one block long or its lowest
- * block has bits set out of the range of the target
- * type, throw an exception.
- * 8. Otherwise, convert the lowest block to the
- * target type, negate it, and return it.
- */
-
-namespace {
- // These masks are used to test whether a Blk has bits
- // set out of the range of a smaller integral type. Note
- // that this range is not considered to include the sign bit.
- const BigUnsigned::Blk lMask = ~0 >> 1;
- const BigUnsigned::Blk uiMask = (unsigned int)(~0);
- const BigUnsigned::Blk iMask = uiMask >> 1;
- const BigUnsigned::Blk usMask = (unsigned short)(~0);
- const BigUnsigned::Blk sMask = usMask >> 1;
+template <class X>
+X BigInteger::convertToUnsignedPrimitive() const {
+ if (sign == negative)
+ throw "BigInteger::to<Primitive>: "
+ "Cannot convert a negative integer to an unsigned type";
+ else
+ return convertBigUnsignedToPrimitiveAccess<X>(mag);
}
-BigInteger::operator unsigned long() const {
- switch (sign) {
- case zero:
+/* Similar to BigUnsigned::convertToPrimitive, but split into two cases for
+ * nonnegative and negative numbers. */
+template <class X, class UX>
+X BigInteger::convertToSignedPrimitive() const {
+ if (sign == zero)
return 0;
- case positive:
- if (len == 1)
- return blk[0];
- else
- throw "BigInteger operator unsigned long() const: Value is too big for an unsigned long";
- case negative:
- throw "BigInteger operator unsigned long() const: Cannot convert a negative integer to an unsigned type";
- default:
- throw "BigInteger: Internal error";
+ else if (mag.getLength() == 1) {
+ // The single block might fit in an X. Try the conversion.
+ Blk b = mag.getBlock(0);
+ if (sign == positive) {
+ X x = X(b);
+ if (x >= 0 && Blk(x) == b)
+ return x;
+ } else {
+ X x = -X(b);
+ /* UX(...) needed to avoid rejecting conversion of
+ * -2^15 to a short. */
+ if (x < 0 && Blk(UX(-x)) == b)
+ return x;
+ }
+ // Otherwise fall through.
}
+ throw "BigInteger::to<Primitive>: "
+ "Value is too big to fit in the requested type";
}
-BigInteger::operator long() const {
- switch (sign) {
- case zero:
- return 0;
- case positive:
- if (len == 1 && (blk[0] & ~lMask) == 0)
- return long(blk[0]);
- else
- throw "BigInteger operator long() const: Value is too big for a long";
- case negative:
- if (len == 1 && (blk[0] & ~lMask) == 0)
- return -long(blk[0]);
- else
- throw "BigInteger operator long() const: Value is too big for a long";
- default:
- throw "BigInteger: Internal error";
- }
+unsigned long BigInteger::toUnsignedLong() const {
+ return convertToUnsignedPrimitive<unsigned long>();
}
-
-BigInteger::operator unsigned int() const {
- switch (sign) {
- case zero:
- return 0;
- case positive:
- if (len == 1 && (blk[0] & ~uiMask) == 0)
- return (unsigned int)(blk[0]);
- else
- throw "BigInteger operator unsigned int() const: Value is too big for an unsigned int";
- case negative:
- throw "BigInteger operator unsigned int() const: Cannot convert a negative integer to an unsigned type";
- default:
- throw "BigInteger: Internal error";
- }
+unsigned int BigInteger::toUnsignedInt() const {
+ return convertToUnsignedPrimitive<unsigned int>();
}
-
-BigInteger::operator int() const {
- switch (sign) {
- case zero:
- return 0;
- case positive:
- if (len == 1 && (blk[0] & ~iMask) == 0)
- return int(blk[0]);
- else
- throw "BigInteger operator int() const: Value is too big for an int";
- case negative:
- if (len == 1 && (blk[0] & ~iMask) == 0)
- return -int(blk[0]);
- else
- throw "BigInteger operator int() const: Value is too big for an int";
- default:
- throw "BigInteger: Internal error";
- }
+unsigned short BigInteger::toUnsignedShort() const {
+ return convertToUnsignedPrimitive<unsigned short>();
}
-
-BigInteger::operator unsigned short() const {
- switch (sign) {
- case zero:
- return 0;
- case positive:
- if (len == 1 && (blk[0] & ~usMask) == 0)
- return (unsigned short)(blk[0]);
- else
- throw "BigInteger operator unsigned short() const: Value is too big for an unsigned short";
- case negative:
- throw "BigInteger operator unsigned short() const: Cannot convert a negative integer to an unsigned type";
- default:
- throw "BigInteger: Internal error";
- }
+long BigInteger::toLong() const {
+ return convertToSignedPrimitive<long, unsigned long>();
}
-
-BigInteger::operator short() const {
- switch (sign) {
- case zero:
- return 0;
- case positive:
- if (len == 1 && (blk[0] & ~sMask) == 0)
- return short(blk[0]);
- else
- throw "BigInteger operator short() const: Value is too big for a short";
- case negative:
- if (len == 1 && (blk[0] & ~sMask) == 0)
- return -short(blk[0]);
- else
- throw "BigInteger operator short() const: Value is too big for a short";
- default:
- throw "BigInteger: Internal error";
- }
+int BigInteger::toInt() const {
+ return convertToSignedPrimitive<int, unsigned int>();
+}
+short BigInteger::toShort() const {
+ return convertToSignedPrimitive<short, unsigned short>();
}
// COMPARISON
return greater;
else switch (sign) {
// If the signs are the same...
- case zero:
+ case zero:
return equal; // Two zeros are equal
- case positive:
+ case positive:
// Compare the magnitudes
- return BigUnsigned::compareTo(x);
- case negative:
+ return mag.compareTo(x.mag);
+ case negative:
// Compare the magnitudes, but return the opposite result
- return CmpRes(-BigUnsigned::compareTo(x));
- default:
- throw "BigInteger: Internal error";
+ return CmpRes(-mag.compareTo(x.mag));
+ default:
+ throw "BigInteger internal error";
}
}
-// PUT-HERE OPERATIONS
-// These do some messing around to determine the sign of the result,
-// then call one of BigUnsigned's put-heres.
+/* COPY-LESS OPERATIONS
+ * These do some messing around to determine the sign of the result,
+ * then call one of BigUnsigned's copy-less operations. */
// See remarks about aliased calls in BigUnsigned.cc .
#define DTRT_ALIASED(cond, op) \
return; \
}
-// Addition
void BigInteger::add(const BigInteger &a, const BigInteger &b) {
DTRT_ALIASED(this == &a || this == &b, add(a, b));
// If one argument is zero, copy the other.
// common sign and add their magnitudes.
else if (a.sign == b.sign) {
sign = a.sign;
- BigUnsigned::add(a, b);
+ mag.add(a.mag, b.mag);
} else {
// Otherwise, their magnitudes must be compared.
- switch (a.BigUnsigned::compareTo(b)) {
+ switch (a.mag.compareTo(b.mag)) {
+ case equal:
// If their magnitudes are the same, copy zero.
- case equal:
- len = 0;
+ mag = 0;
sign = zero;
break;
// Otherwise, take the sign of the greater, and subtract
// the lesser magnitude from the greater magnitude.
- case greater:
+ case greater:
sign = a.sign;
- BigUnsigned::subtract(a, b);
+ mag.subtract(a.mag, b.mag);
break;
- case less:
+ case less:
sign = b.sign;
- BigUnsigned::subtract(b, a);
+ mag.subtract(b.mag, a.mag);
break;
}
}
}
-// Subtraction
void BigInteger::subtract(const BigInteger &a, const BigInteger &b) {
// Notice that this routine is identical to BigInteger::add,
// if one replaces b.sign by its opposite.
DTRT_ALIASED(this == &a || this == &b, subtract(a, b));
// If a is zero, copy b and flip its sign. If b is zero, copy a.
if (a.sign == zero) {
- BigUnsigned::operator =(b);
+ mag = b.mag;
// Take the negative of _b_'s, sign, not ours.
// Bug pointed out by Sam Larkin on 2005.03.30.
sign = Sign(-b.sign);
// If their signs differ, take a.sign and add the magnitudes.
else if (a.sign != b.sign) {
sign = a.sign;
- BigUnsigned::add(a, b);
+ mag.add(a.mag, b.mag);
} else {
// Otherwise, their magnitudes must be compared.
- switch (a.BigUnsigned::compareTo(b)) {
+ switch (a.mag.compareTo(b.mag)) {
// If their magnitudes are the same, copy zero.
- case equal:
- len = 0;
+ case equal:
+ mag = 0;
sign = zero;
break;
// If a's magnitude is greater, take a.sign and
// subtract a from b.
- case greater:
+ case greater:
sign = a.sign;
- BigUnsigned::subtract(a, b);
+ mag.subtract(a.mag, b.mag);
break;
// If b's magnitude is greater, take the opposite
// of b.sign and subtract b from a.
- case less:
+ case less:
sign = Sign(-b.sign);
- BigUnsigned::subtract(b, a);
+ mag.subtract(b.mag, a.mag);
break;
}
}
}
-// Multiplication
void BigInteger::multiply(const BigInteger &a, const BigInteger &b) {
DTRT_ALIASED(this == &a || this == &b, multiply(a, b));
// If one object is zero, copy zero and return.
if (a.sign == zero || b.sign == zero) {
sign = zero;
- len = 0;
+ mag = 0;
return;
}
// If the signs of the arguments are the same, the result
// is positive, otherwise it is negative.
sign = (a.sign == b.sign) ? positive : negative;
// Multiply the magnitudes.
- BigUnsigned::multiply(a, b);
+ mag.multiply(a.mag, b.mag);
}
/*
// Division by zero gives quotient 0 and remainder *this
if (b.sign == zero) {
- q.len = 0;
+ q.mag = 0;
q.sign = zero;
return;
}
// 0 / b gives quotient 0 and remainder 0
if (sign == zero) {
- q.len = 0;
+ q.mag = 0;
q.sign = zero;
return;
}
// No: harder case. Quotient is negative.
q.sign = negative;
// Decrease the magnitude of the dividend by one.
- BigUnsigned::operator --();
+ mag--;
/*
* We tinker with the dividend before and with the
* quotient and remainder after so that the result
}
// Divide the magnitudes.
- BigUnsigned::divideWithRemainder(b, q);
+ mag.divideWithRemainder(b.mag, q.mag);
if (sign != b.sign) {
// More for the harder case (as described):
// Increase the magnitude of the quotient by one.
- q.BigUnsigned::operator ++();
+ q.mag++;
// Modify the remainder.
- BigUnsigned temp(*this);
- BigUnsigned::subtract(b, temp);
- BigUnsigned::operator --();
+ mag.subtract(b.mag, mag);
+ mag--;
}
// Sign of the remainder is always the sign of the divisor b.
sign = b.sign;
// Set signs to zero as necessary. (Thanks David Allen!)
- if (len == 0)
+ if (mag.isZero())
sign = zero;
- if (q.len == 0)
+ if (q.mag.isZero())
q.sign = zero;
// WHEW!!!
void BigInteger::negate(const BigInteger &a) {
DTRT_ALIASED(this == &a, negate(a));
// Copy a's magnitude
- BigUnsigned::operator =(a);
+ mag = a.mag;
// Copy the opposite of a.sign
sign = Sign(-a.sign);
}
// Prefix increment
void BigInteger::operator ++() {
- switch (sign) {
- case zero:
- allocate(1);
- sign = positive;
- len = 1;
- blk[0] = 1;
- break;
- case positive:
- BigUnsigned::operator ++();
- break;
- case negative:
- BigUnsigned::operator --();
- if (len == 0)
+ if (sign == negative) {
+ mag--;
+ if (mag == 0)
sign = zero;
- break;
+ } else {
+ mag++;
+ sign = positive; // if not already
}
}
// Prefix decrement
void BigInteger::operator --() {
- switch (sign) {
- case zero:
- allocate(1);
- sign = negative;
- len = 1;
- blk[0] = 1;
- break;
- case negative:
- BigUnsigned::operator ++();
- break;
- case positive:
- BigUnsigned::operator --();
- if (len == 0)
+ if (sign == positive) {
+ mag--;
+ if (mag == 0)
sign = zero;
- break;
+ } else {
+ mag++;
+ sign = negative;
}
}