Merge to update docs and contributions #504

Merged
altavir merged 199 commits from dev into master 2022-10-03 20:58:00 +03:00
7 changed files with 998 additions and 168 deletions
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@ -154,7 +154,7 @@ public interface AbstractPolynomialSpace<C, P: AbstractPolynomial<C>> : Ring<P>
* Check if the instant is NOT zero constant.
*/
@JvmName("constantIsNotZero")
public fun C.isNotZero(): Boolean
public fun C.isNotZero(): Boolean = !isZero()
/**
* Check if the instant is unit constant.
*/
@ -164,7 +164,7 @@ public interface AbstractPolynomialSpace<C, P: AbstractPolynomial<C>> : Ring<P>
* Check if the instant is NOT unit constant.
*/
@JvmName("constantIsNotOne")
public fun C.isNotOne(): Boolean
public fun C.isNotOne(): Boolean = !isOne()
/**
* Check if the instant is minus unit constant.
*/
@ -174,7 +174,7 @@ public interface AbstractPolynomialSpace<C, P: AbstractPolynomial<C>> : Ring<P>
* Check if the instant is NOT minus unit constant.
*/
@JvmName("constantIsNotMinusOne")
public fun C.isNotMinusOne(): Boolean
public fun C.isNotMinusOne(): Boolean = !isMinusOne()
// endregion
// region Constant-polynomial relation
@ -232,27 +232,27 @@ public interface AbstractPolynomialSpace<C, P: AbstractPolynomial<C>> : Ring<P>
/**
* Check if the instant is zero polynomial.
*/
public fun P.isZero(): Boolean = this == zero
public fun P.isZero(): Boolean = this equalsTo zero
/**
* Check if the instant is NOT zero polynomial.
*/
public fun P.isNotZero(): Boolean = this != zero
public fun P.isNotZero(): Boolean = !isZero()
/**
* Check if the instant is unit polynomial.
*/
public fun P.isOne(): Boolean = this == one
public fun P.isOne(): Boolean = this equalsTo one
/**
* Check if the instant is NOT unit polynomial.
*/
public fun P.isNotOne(): Boolean = this != one
public fun P.isNotOne(): Boolean = !isOne()
/**
* Check if the instant is minus unit polynomial.
*/
public fun P.isMinusOne(): Boolean = this == -one
public fun P.isMinusOne(): Boolean = this equalsTo -one
/**
* Check if the instant is NOT minus unit polynomial.
*/
public fun P.isNotMinusOne(): Boolean = this != -one
public fun P.isNotMinusOne(): Boolean = !isMinusOne()
/**
* Instance of zero polynomial (zero of the polynomial ring).
@ -266,8 +266,11 @@ public interface AbstractPolynomialSpace<C, P: AbstractPolynomial<C>> : Ring<P>
/**
* Checks equality of the polynomials.
*/
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
public fun P.equals(other: P): Boolean
public infix fun P.equalsTo(other: P): Boolean
/**
* Checks NOT equality of the polynomials.
*/
public infix fun P.notEqualsTo(other: P): Boolean = !(this equalsTo other)
// endregion
// Not sure is it necessary...
@ -311,3 +314,106 @@ public interface AbstractPolynomialSpace<C, P: AbstractPolynomial<C>> : Ring<P>
override fun multiply(left: P, right: P): P = left * right
// endregion
}
/**
* Abstraction of ring of polynomials of type [P] over ring of constants of type [C].
*
* @param C the type of constants. Polynomials have them as a coefficients in their terms.
* @param P the type of polynomials.
*/
@Suppress("INAPPLICABLE_JVM_NAME", "PARAMETER_NAME_CHANGED_ON_OVERRIDE")
public interface AbstractPolynomialSpaceOverRing<C, P: AbstractPolynomial<C>, A: Ring<C>> : AbstractPolynomialSpace<C, P> {
public val ring: A
// region Constant-integer relation
/**
* Returns sum of the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to adding [other] copies of unit of underlying ring to [this].
*/
@JvmName("constantIntPlus")
public override operator fun C.plus(other: Int): C = ring { optimizedAddMultiplied(this@plus, one, other) }
/**
* Returns difference between the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to subtraction [other] copies of unit of underlying ring from [this].
*/
@JvmName("constantIntMinus")
public override operator fun C.minus(other: Int): C = ring { optimizedAddMultiplied(this@minus, one, -other) }
/**
* Returns product of the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to sum of [other] copies of [this].
*/
@JvmName("constantIntTimes")
public override operator fun C.times(other: Int): C = ring { optimizedMultiply(this@times, other) }
// endregion
// region Integer-constant relation
/**
* Returns sum of the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to adding [this] copies of unit of underlying ring to [other].
*/
@JvmName("intConstantPlus")
public override operator fun Int.plus(other: C): C = ring { optimizedAddMultiplied(other, one, this@plus) }
/**
* Returns difference between the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to subtraction [this] copies of unit of underlying ring from [other].
*/
@JvmName("intConstantMinus")
public override operator fun Int.minus(other: C): C = ring { optimizedAddMultiplied(-other, one, this@minus) }
/**
* Returns product of the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to sum of [this] copies of [other].
*/
@JvmName("intConstantTimes")
public override operator fun Int.times(other: C): C = ring { optimizedMultiply(other, this@times) }
// endregion
// region Constant-constant relation
/**
* Returns negation of the constant.
*/
@JvmName("constantUnaryMinus")
@JsName("constantUnaryMinus")
public override operator fun C.unaryMinus(): C = ring { -this@unaryMinus }
/**
* Returns sum of the constants.
*/
@JvmName("constantPlus")
@JsName("constantPlus")
public override operator fun C.plus(other: C): C = ring { this@plus + other }
/**
* Returns difference of the constants.
*/
@JvmName("constantMinus")
@JsName("constantMinus")
public override operator fun C.minus(other: C): C = ring { this@minus - other }
/**
* Returns product of the constants.
*/
@JvmName("constantTimes")
@JsName("constantTimes")
public override operator fun C.times(other: C): C = ring { this@times * other }
/**
* Check if the instant is zero constant.
*/
@JvmName("constantIsZero")
public override fun C.isZero(): Boolean = ring { this == zero }
/**
* Check if the instant is unit constant.
*/
@JvmName("constantIsOne")
public override fun C.isOne(): Boolean = ring { this == one }
/**
* Check if the instant is minus unit constant.
*/
@JvmName("constantIsMinusOne")
public override fun C.isMinusOne(): Boolean = ring { this == -one }
// endregion
}

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@ -13,7 +13,12 @@ import kotlin.jvm.JvmName
/**
* Abstraction of rational function.
*/
public interface AbstractRationalFunction<C, P: AbstractPolynomial<C>>
public interface AbstractRationalFunction<C, P: AbstractPolynomial<C>> {
public val numerator: P
public val denominator: P
public operator fun component1(): P = numerator
public operator fun component2(): P = denominator
}
@Suppress("INAPPLICABLE_JVM_NAME", "PARAMETER_NAME_CHANGED_ON_OVERRIDE")
public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R: AbstractRationalFunction<C, P>> : Ring<R> {
@ -190,7 +195,7 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
* Check if the instant is NOT zero constant.
*/
@JvmName("constantIsNotZero")
public fun C.isNotZero(): Boolean
public fun C.isNotZero(): Boolean = !isZero()
/**
* Check if the instant is unit constant.
*/
@ -200,7 +205,7 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
* Check if the instant is NOT unit constant.
*/
@JvmName("constantIsNotOne")
public fun C.isNotOne(): Boolean
public fun C.isNotOne(): Boolean = !isOne()
/**
* Check if the instant is minus unit constant.
*/
@ -210,7 +215,7 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
* Check if the instant is NOT minus unit constant.
*/
@JvmName("constantIsNotMinusOne")
public fun C.isNotMinusOne(): Boolean
public fun C.isNotMinusOne(): Boolean = !isMinusOne()
// endregion
// region Constant-polynomial relation
@ -268,42 +273,45 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
/**
* Check if the instant is zero polynomial.
*/
public fun P.isZero(): Boolean = this == zeroPolynomial
public fun P.isZero(): Boolean = this equalsTo polynomialZero
/**
* Check if the instant is NOT zero polynomial.
*/
public fun P.isNotZero(): Boolean = this != zeroPolynomial
public fun P.isNotZero(): Boolean = !isZero()
/**
* Check if the instant is unit polynomial.
*/
public fun P.isOne(): Boolean = this == onePolynomial
public fun P.isOne(): Boolean = this equalsTo polynomialOne
/**
* Check if the instant is NOT unit polynomial.
*/
public fun P.isNotOne(): Boolean = this != onePolynomial
public fun P.isNotOne(): Boolean = !isOne()
/**
* Check if the instant is minus unit polynomial.
*/
public fun P.isMinusOne(): Boolean = this == -onePolynomial
public fun P.isMinusOne(): Boolean = this equalsTo -polynomialOne
/**
* Check if the instant is NOT minus unit polynomial.
*/
public fun P.isNotMinusOne(): Boolean = this != -onePolynomial
public fun P.isNotMinusOne(): Boolean = !isMinusOne()
/**
* Instance of zero polynomial (zero of the polynomial ring).
*/
public val zeroPolynomial: P
public val polynomialZero: P
/**
* Instance of unit polynomial (unit of the polynomial ring).
*/
public val onePolynomial: P
public val polynomialOne: P
/**
* Checks equality of the polynomials.
*/
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
public fun P.equals(other: P): Boolean
public infix fun P.equalsTo(other: P): Boolean
/**
* Checks NOT equality of the polynomials.
*/
public infix fun P.notEqualsTo(other: P): Boolean = !(this equalsTo other)
// endregion
// region Constant-rational relation
@ -391,27 +399,27 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
/**
* Check if the instant is zero rational function.
*/
public fun R.isZero(): Boolean = this == zero
public fun R.isZero(): Boolean = this equalsTo zero
/**
* Check if the instant is NOT zero rational function.
*/
public fun R.isNotZero(): Boolean = this != zero
public fun R.isNotZero(): Boolean = !isZero()
/**
* Check if the instant is unit rational function.
*/
public fun R.isOne(): Boolean = this == one
public fun R.isOne(): Boolean = this equalsTo one
/**
* Check if the instant is NOT unit rational function.
*/
public fun R.isNotOne(): Boolean = this != one
public fun R.isNotOne(): Boolean = !isOne()
/**
* Check if the instant is minus unit rational function.
*/
public fun R.isMinusOne(): Boolean = this == -one
public fun R.isMinusOne(): Boolean = this equalsTo -one
/**
* Check if the instant is NOT minus unit rational function.
*/
public fun R.isNotMinusOne(): Boolean = this != -one
public fun R.isNotMinusOne(): Boolean = !isMinusOne()
/**
* Instance of zero rational function (zero of the rational functions ring).
@ -425,8 +433,11 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
/**
* Checks equality of the rational functions.
*/
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
public fun R.equals(other: R): Boolean
public infix fun R.equalsTo(other: R): Boolean
/**
* Checks NOT equality of the polynomials.
*/
public infix fun R.notEqualsTo(other: R): Boolean = !(this equalsTo other)
// endregion
// Not sure is it necessary...
@ -453,35 +464,31 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
* Checks if the instant is **not** constant non-zero polynomial (of degree no more than 0) over considered ring.
*/
public fun P.isNotNonZeroConstant(): Boolean = !isNonZeroConstant()
/**
* If polynomial is a constant polynomial represents and returns it as constant.
* Otherwise, (when the polynomial is not constant polynomial) returns `null`.
*/
public fun P.asConstantOrNull(): C?
/**
* If polynomial is a constant polynomial represents and returns it as constant.
* Otherwise, (when the polynomial is not constant polynomial) raises corresponding exception.
*/
public fun P.asConstant(): C = asConstantOrNull() ?: error("Can not represent non-constant polynomial as a constant")
// endregion
// Not sure is it necessary...
// region Polynomial properties
// region Rational properties
/**
* Checks if the instant is constant polynomial (of degree no more than 0) over considered ring.
* Degree of the polynomial, [see also](https://en.wikipedia.org/wiki/Degree_of_a_polynomial). If the polynomial is
* zero, degree is -1.
*/
public fun R.isConstant(): Boolean
public val R.numeratorDegree: Int get() = numerator.degree
/**
* Checks if the instant is **not** constant polynomial (of degree no more than 0) over considered ring.
* Degree of the polynomial, [see also](https://en.wikipedia.org/wiki/Degree_of_a_polynomial). If the polynomial is
* zero, degree is -1.
*/
public fun R.isNotConstant(): Boolean = !isConstant()
/**
* Checks if the instant is constant non-zero polynomial (of degree no more than 0) over considered ring.
*/
public fun R.isNonZeroConstant(): Boolean
/**
* Checks if the instant is **not** constant non-zero polynomial (of degree no more than 0) over considered ring.
*/
public fun R.isNotNonZeroConstant(): Boolean = !isNonZeroConstant()
public fun R.asConstantOrNull(): C?
public fun R.asConstant(): C = asConstantOrNull() ?: error("Can not represent non-constant polynomial as a constant")
public val R.denominatorDegree: Int get() = denominator.degree
// TODO: Перенести в реализацию
// fun R.substitute(argument: C): C
@ -503,3 +510,414 @@ public interface AbstractRationalFunctionalSpace<C, P: AbstractPolynomial<C>, R:
override fun multiply(left: R, right: R): R = left * right
// endregion
}
@Suppress("INAPPLICABLE_JVM_NAME", "PARAMETER_NAME_CHANGED_ON_OVERRIDE")
public interface AbstractRationalFunctionalSpaceOverRing<C, P: AbstractPolynomial<C>, R: AbstractRationalFunction<C, P>, A: Ring<C>> : AbstractRationalFunctionalSpace<C, P, R> {
public val ring: A
// region Constant-integer relation
/**
* Returns sum of the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to adding [other] copies of unit of underlying ring to [this].
*/
@JvmName("constantIntPlus")
public override operator fun C.plus(other: Int): C = ring { optimizedAddMultiplied(this@plus, one, other) }
/**
* Returns difference between the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to subtraction [other] copies of unit of underlying ring from [this].
*/
@JvmName("constantIntMinus")
public override operator fun C.minus(other: Int): C = ring { optimizedAddMultiplied(this@minus, one, -other) }
/**
* Returns product of the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to sum of [other] copies of [this].
*/
@JvmName("constantIntTimes")
public override operator fun C.times(other: Int): C = ring { optimizedMultiply(this@times, other) }
// endregion
// region Integer-constant relation
/**
* Returns sum of the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to adding [this] copies of unit of underlying ring to [other].
*/
@JvmName("intConstantPlus")
public override operator fun Int.plus(other: C): C = ring { optimizedAddMultiplied(other, one, this@plus) }
/**
* Returns difference between the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to subtraction [this] copies of unit of underlying ring from [other].
*/
@JvmName("intConstantMinus")
public override operator fun Int.minus(other: C): C = ring { optimizedAddMultiplied(-other, one, this@minus) }
/**
* Returns product of the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to sum of [this] copies of [other].
*/
@JvmName("intConstantTimes")
public override operator fun Int.times(other: C): C = ring { optimizedMultiply(other, this@times) }
// endregion
// region Constant-constant relation
/**
* Returns the same constant.
*/
@JvmName("constantUnaryPlus")
@JsName("constantUnaryPlus")
public override operator fun C.unaryPlus(): C = ring { +this@unaryPlus }
/**
* Returns negation of the constant.
*/
@JvmName("constantUnaryMinus")
@JsName("constantUnaryMinus")
public override operator fun C.unaryMinus(): C = ring { -this@unaryMinus }
/**
* Returns sum of the constants.
*/
@JvmName("constantPlus")
@JsName("constantPlus")
public override operator fun C.plus(other: C): C = ring { this@plus + other }
/**
* Returns difference of the constants.
*/
@JvmName("constantMinus")
@JsName("constantMinus")
public override operator fun C.minus(other: C): C = ring { this@minus - other }
/**
* Returns product of the constants.
*/
@JvmName("constantTimes")
@JsName("constantTimes")
public override operator fun C.times(other: C): C = ring { this@times * other }
/**
* Check if the instant is zero constant.
*/
@JvmName("constantIsZero")
public override fun C.isZero(): Boolean = ring { this@isZero.isZero() }
/**
* Check if the instant is NOT zero constant.
*/
@JvmName("constantIsNotZero")
public override fun C.isNotZero(): Boolean = ring { this@isNotZero.isNotZero() }
/**
* Check if the instant is unit constant.
*/
@JvmName("constantIsOne")
public override fun C.isOne(): Boolean = ring { this@isOne.isOne() }
/**
* Check if the instant is NOT unit constant.
*/
@JvmName("constantIsNotOne")
public override fun C.isNotOne(): Boolean = ring { this@isNotOne.isNotOne() }
/**
* Check if the instant is minus unit constant.
*/
@JvmName("constantIsMinusOne")
public override fun C.isMinusOne(): Boolean = ring { this@isMinusOne.isMinusOne() }
/**
* Check if the instant is NOT minus unit constant.
*/
@JvmName("constantIsNotMinusOne")
public override fun C.isNotMinusOne(): Boolean = ring { this@isNotMinusOne.isNotMinusOne() }
// endregion
}
@Suppress("INAPPLICABLE_JVM_NAME", "PARAMETER_NAME_CHANGED_ON_OVERRIDE")
public interface AbstractRationalFunctionalSpaceOverPolynomialSpace<C, P: AbstractPolynomial<C>, R: AbstractRationalFunction<C, P>, A: Ring<C>> : AbstractRationalFunctionalSpace<C, P, R> {
public val polynomialRing: AbstractPolynomialSpace<C, P>
// region Constant-integer relation
/**
* Returns sum of the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to adding [other] copies of unit of underlying ring to [this].
*/
@JvmName("constantIntPlus")
public override operator fun C.plus(other: Int): C = polynomialRing { this@plus + other }
/**
* Returns difference between the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to subtraction [other] copies of unit of underlying ring from [this].
*/
@JvmName("constantIntMinus")
public override operator fun C.minus(other: Int): C = polynomialRing { this@minus - other }
/**
* Returns product of the constant and the integer represented as constant (member of underlying ring).
*
* The operation is equivalent to sum of [other] copies of [this].
*/
@JvmName("constantIntTimes")
public override operator fun C.times(other: Int): C = polynomialRing { this@times * other }
// endregion
// region Integer-constant relation
/**
* Returns sum of the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to adding [this] copies of unit of underlying ring to [other].
*/
@JvmName("intConstantPlus")
public override operator fun Int.plus(other: C): C = polynomialRing { this@plus + other }
/**
* Returns difference between the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to subtraction [this] copies of unit of underlying ring from [other].
*/
@JvmName("intConstantMinus")
public override operator fun Int.minus(other: C): C = polynomialRing { this@minus - other }
/**
* Returns product of the integer represented as constant (member of underlying ring) and the constant.
*
* The operation is equivalent to sum of [this] copies of [other].
*/
@JvmName("intConstantTimes")
public override operator fun Int.times(other: C): C = polynomialRing { this@times * other }
// endregion
// region Polynomial-integer relation
/**
* Returns sum of the constant and the integer represented as polynomial.
*
* The operation is equivalent to adding [other] copies of unit polynomial to [this].
*/
public override operator fun P.plus(other: Int): P = polynomialRing { this@plus + other }
/**
* Returns difference between the constant and the integer represented as polynomial.
*
* The operation is equivalent to subtraction [other] copies of unit polynomial from [this].
*/
public override operator fun P.minus(other: Int): P = polynomialRing { this@minus - other }
/**
* Returns product of the constant and the integer represented as polynomial.
*
* The operation is equivalent to sum of [other] copies of [this].
*/
public override operator fun P.times(other: Int): P = polynomialRing { this@times * other }
// endregion
// region Integer-polynomial relation
/**
* Returns sum of the integer represented as polynomial and the constant.
*
* The operation is equivalent to adding [this] copies of unit polynomial to [other].
*/
public override operator fun Int.plus(other: P): P = polynomialRing { this@plus + other }
/**
* Returns difference between the integer represented as polynomial and the constant.
*
* The operation is equivalent to subtraction [this] copies of unit polynomial from [other].
*/
public override operator fun Int.minus(other: P): P = polynomialRing { this@minus - other }
/**
* Returns product of the integer represented as polynomial and the constant.
*
* The operation is equivalent to sum of [this] copies of [other].
*/
public override operator fun Int.times(other: P): P = polynomialRing { this@times * other }
// endregion
// region Constant-constant relation
/**
* Returns the same constant.
*/
@JvmName("constantUnaryPlus")
@JsName("constantUnaryPlus")
public override operator fun C.unaryPlus(): C = polynomialRing { +this@unaryPlus }
/**
* Returns negation of the constant.
*/
@JvmName("constantUnaryMinus")
@JsName("constantUnaryMinus")
public override operator fun C.unaryMinus(): C = polynomialRing { -this@unaryMinus }
/**
* Returns sum of the constants.
*/
@JvmName("constantPlus")
@JsName("constantPlus")
public override operator fun C.plus(other: C): C = polynomialRing { this@plus + other }
/**
* Returns difference of the constants.
*/
@JvmName("constantMinus")
@JsName("constantMinus")
public override operator fun C.minus(other: C): C = polynomialRing { this@minus - other }
/**
* Returns product of the constants.
*/
@JvmName("constantTimes")
@JsName("constantTimes")
public override operator fun C.times(other: C): C = polynomialRing { this@times * other }
/**
* Check if the instant is zero constant.
*/
@JvmName("constantIsZero")
public override fun C.isZero(): Boolean = polynomialRing { this@isZero.isZero() }
/**
* Check if the instant is NOT zero constant.
*/
@JvmName("constantIsNotZero")
public override fun C.isNotZero(): Boolean = polynomialRing { this@isNotZero.isNotZero() }
/**
* Check if the instant is unit constant.
*/
@JvmName("constantIsOne")
public override fun C.isOne(): Boolean = polynomialRing { this@isOne.isOne() }
/**
* Check if the instant is NOT unit constant.
*/
@JvmName("constantIsNotOne")
public override fun C.isNotOne(): Boolean = polynomialRing { this@isNotOne.isNotOne() }
/**
* Check if the instant is minus unit constant.
*/
@JvmName("constantIsMinusOne")
public override fun C.isMinusOne(): Boolean = polynomialRing { this@isMinusOne.isMinusOne() }
/**
* Check if the instant is NOT minus unit constant.
*/
@JvmName("constantIsNotMinusOne")
public override fun C.isNotMinusOne(): Boolean = polynomialRing { this@isNotMinusOne.isNotMinusOne() }
// endregion
// region Constant-polynomial relation
/**
* Returns sum of the constant represented as polynomial and the polynomial.
*/
public override operator fun C.plus(other: P): P = polynomialRing { this@plus + other }
/**
* Returns difference between the constant represented as polynomial and the polynomial.
*/
public override operator fun C.minus(other: P): P = polynomialRing { this@minus - other }
/**
* Returns product of the constant represented as polynomial and the polynomial.
*/
public override operator fun C.times(other: P): P = polynomialRing { this@times * other }
// endregion
// region Polynomial-constant relation
/**
* Returns sum of the constant represented as polynomial and the polynomial.
*/
public override operator fun P.plus(other: C): P = polynomialRing { this@plus + other }
/**
* Returns difference between the constant represented as polynomial and the polynomial.
*/
public override operator fun P.minus(other: C): P = polynomialRing { this@minus - other }
/**
* Returns product of the constant represented as polynomial and the polynomial.
*/
public override operator fun P.times(other: C): P = polynomialRing { this@times * other }
// endregion
// region Polynomial-polynomial relation
/**
* Returns the same polynomial.
*/
public override operator fun P.unaryPlus(): P = polynomialRing { +this@unaryPlus }
/**
* Returns negation of the polynomial.
*/
public override operator fun P.unaryMinus(): P = polynomialRing { -this@unaryMinus }
/**
* Returns sum of the polynomials.
*/
public override operator fun P.plus(other: P): P = polynomialRing { this@plus + other }
/**
* Returns difference of the polynomials.
*/
public override operator fun P.minus(other: P): P = polynomialRing { this@minus - other }
/**
* Returns product of the polynomials.
*/
public override operator fun P.times(other: P): P = polynomialRing { this@times * other }
/**
* Check if the instant is zero polynomial.
*/
public override fun P.isZero(): Boolean = polynomialRing { this@isZero.isZero() }
/**
* Check if the instant is NOT zero polynomial.
*/
public override fun P.isNotZero(): Boolean = polynomialRing { this@isNotZero.isNotZero() }
/**
* Check if the instant is unit polynomial.
*/
public override fun P.isOne(): Boolean = polynomialRing { this@isOne.isOne() }
/**
* Check if the instant is NOT unit polynomial.
*/
public override fun P.isNotOne(): Boolean = polynomialRing { this@isNotOne.isNotOne() }
/**
* Check if the instant is minus unit polynomial.
*/
public override fun P.isMinusOne(): Boolean = polynomialRing { this@isMinusOne.isMinusOne() }
/**
* Check if the instant is NOT minus unit polynomial.
*/
public override fun P.isNotMinusOne(): Boolean = polynomialRing { this@isNotMinusOne.isNotMinusOne() }
/**
* Instance of zero polynomial (zero of the polynomial ring).
*/
public override val polynomialZero: P get() = polynomialRing.zero
/**
* Instance of unit polynomial (unit of the polynomial ring).
*/
public override val polynomialOne: P get() = polynomialRing.one
/**
* Checks equality of the polynomials.
*/
public override infix fun P.equalsTo(other: P): Boolean = polynomialRing { this@equalsTo equalsTo other }
/**
* Checks NOT equality of the polynomials.
*/
public override infix fun P.notEqualsTo(other: P): Boolean = polynomialRing { this@notEqualsTo notEqualsTo other }
// endregion
// Not sure is it necessary...
// region Polynomial properties
/**
* Degree of the polynomial, [see also](https://en.wikipedia.org/wiki/Degree_of_a_polynomial). If the polynomial is
* zero, degree is -1.
*/
public override val P.degree: Int get() = polynomialRing { this@degree.degree }
/**
* Checks if the instant is constant polynomial (of degree no more than 0) over considered ring.
*/
public override fun P.isConstant(): Boolean = polynomialRing { this@isConstant.isConstant() }
/**
* Checks if the instant is **not** constant polynomial (of degree no more than 0) over considered ring.
*/
public override fun P.isNotConstant(): Boolean = polynomialRing { this@isNotConstant.isNotConstant() }
/**
* Checks if the instant is constant non-zero polynomial (of degree no more than 0) over considered ring.
*/
public override fun P.isNonZeroConstant(): Boolean = polynomialRing { this@isNonZeroConstant.isNonZeroConstant() }
/**
* Checks if the instant is **not** constant non-zero polynomial (of degree no more than 0) over considered ring.
*/
public override fun P.isNotNonZeroConstant(): Boolean = polynomialRing { this@isNotNonZeroConstant.isNotNonZeroConstant() }
/**
* If polynomial is a constant polynomial represents and returns it as constant.
* Otherwise, (when the polynomial is not constant polynomial) returns `null`.
*/
public override fun P.asConstantOrNull(): C? = polynomialRing { this@asConstantOrNull.asConstantOrNull() }
/**
* If polynomial is a constant polynomial represents and returns it as constant.
* Otherwise, (when the polynomial is not constant polynomial) raises corresponding exception.
*/
public override fun P.asConstant(): C = polynomialRing { this@asConstant.asConstant() }
// endregion
}

View File

@ -13,7 +13,7 @@ import kotlin.math.max
*
* @param C Ring in which the polynomial is considered.
*/
public class LabeledPolynomial<C>
public data class LabeledPolynomial<C>
internal constructor(
/**
* Map that collects coefficients of the polynomial. Every non-zero monomial
@ -788,7 +788,7 @@ public class LabeledPolynomialSpace<C, A : Ring<C>>(
isZero() -> zero
other.isZero() -> zero
else -> LabeledPolynomial<C>(
buildCoefficients {
buildCoefficients(coefficients.size * other.coefficients.size) {
for ((degs1, c1) in coefficients) for ((degs2, c2) in other.coefficients) {
val degs = degs1.toMutableMap()
degs2.mapValuesTo(degs) { (variable, deg) -> degs.getOrElse(variable) { 0u } + deg }
@ -804,7 +804,7 @@ public class LabeledPolynomialSpace<C, A : Ring<C>>(
// TODO: Docs
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
override fun LabeledPolynomial<C>.equals(other: LabeledPolynomial<C>): Boolean =
override infix fun LabeledPolynomial<C>.equalsTo(other: LabeledPolynomial<C>): Boolean =
when {
this === other -> true
else -> coefficients.size == other.coefficients.size &&
@ -896,15 +896,9 @@ public class LabeledPolynomialSpace<C, A : Ring<C>>(
// public inline operator fun LabeledPolynomial<C>.invoke(argument: Map<Variable, LabeledPolynomial<C>>): LabeledPolynomial<C> = this.substitute(ring, argument)
// endregion
// region Legacy
@Suppress("OVERRIDE_BY_INLINE", "NOTHING_TO_INLINE")
override inline fun add(left: LabeledPolynomial<C>, right: LabeledPolynomial<C>): LabeledPolynomial<C> = left + right
@Suppress("OVERRIDE_BY_INLINE", "NOTHING_TO_INLINE")
override inline fun multiply(left: LabeledPolynomial<C>, right: LabeledPolynomial<C>): LabeledPolynomial<C> = left * right
// endregion
// region Utilities
// TODO: Move to region internal utilities with context receiver
@JvmName("applyAndRemoveZerosInternal")
internal fun MutableMap<Map<Variable, UInt>, C>.applyAndRemoveZeros(block: MutableMap<Map<Variable, UInt>, C>.() -> Unit) : MutableMap<Map<Variable, UInt>, C> {
contract {
callsInPlace(block, InvocationKind.EXACTLY_ONCE)
@ -916,12 +910,20 @@ public class LabeledPolynomialSpace<C, A : Ring<C>>(
internal fun Map<Map<Variable, UInt>, C>.applyAndRemoveZeros(block: MutableMap<Map<Variable, UInt>, C>.() -> Unit) : Map<Map<Variable, UInt>, C> =
toMutableMap().applyAndRemoveZeros(block)
@OptIn(ExperimentalTypeInference::class)
internal fun buildCoefficients(@BuilderInference builderAction: MutableMap<Map<Variable, UInt>, C>.() -> Unit): Map<Map<Variable, UInt>, C> {
internal inline fun buildCoefficients(@BuilderInference builderAction: MutableMap<Map<Variable, UInt>, C>.() -> Unit): Map<Map<Variable, UInt>, C> {
contract { callsInPlace(builderAction, InvocationKind.EXACTLY_ONCE) }
return buildMap {
builderAction()
for ((degs, c) in this) if (c.isZero()) this.remove(degs)
}
}
@OptIn(ExperimentalTypeInference::class)
internal inline fun buildCoefficients(capacity: Int, @BuilderInference builderAction: MutableMap<Map<Variable, UInt>, C>.() -> Unit): Map<Map<Variable, UInt>, C> {
contract { callsInPlace(builderAction, InvocationKind.EXACTLY_ONCE) }
return buildMap(capacity) {
builderAction()
for ((degs, c) in this) if (c.isZero()) this.remove(degs)
}
}
// endregion
}

View File

@ -13,7 +13,7 @@ import kotlin.math.max
*
* @param C the type of constants.
*/
public class NumberedPolynomial<C>
public data class NumberedPolynomial<C>
internal constructor(
/**
* Map that collects coefficients of the polynomial. Every monomial `a x_1^{d_1} ... x_n^{d_n}` is represented as
@ -259,27 +259,9 @@ public fun <C, A: Ring<C>> C.asNumberedPolynomial() : NumberedPolynomial<C> = Nu
* @param ring the [A] instance.
*/
@Suppress("PARAMETER_NAME_CHANGED_ON_OVERRIDE", "INAPPLICABLE_JVM_NAME")
public class NumberedPolynomialSpace<C, A : Ring<C>>(
public val ring: A,
) : AbstractPolynomialSpace<C, NumberedPolynomial<C>> {
// region Constant-integer relation
@JvmName("constantIntPlus")
public override operator fun C.plus(other: Int): C = ring { optimizedAddMultiplied(this@plus, one, other) }
@JvmName("constantIntMinus")
public override operator fun C.minus(other: Int): C = ring { optimizedAddMultiplied(this@minus, one, -other) }
@JvmName("constantIntTimes")
public override operator fun C.times(other: Int): C = ring { optimizedMultiply(this@times, other) }
// endregion
// region Integer-constant relation
@JvmName("intConstantPlus")
public override operator fun Int.plus(other: C): C = ring { optimizedAddMultiplied(other, one, this@plus) }
@JvmName("intConstantMinus")
public override operator fun Int.minus(other: C): C = ring { optimizedAddMultiplied(-other, one, this@minus) }
@JvmName("intConstantTimes")
public override operator fun Int.times(other: C): C = ring { optimizedMultiply(other, this@times) }
// endregion
public open class NumberedPolynomialSpace<C, A : Ring<C>>(
public final override val ring: A,
) : AbstractPolynomialSpaceOverRing<C, NumberedPolynomial<C>, A> {
// region Polynomial-integer relation
public override operator fun NumberedPolynomial<C>.plus(other: Int): NumberedPolynomial<C> =
if (other == 0) this
@ -362,29 +344,6 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
)
// endregion
// region Constant-constant relation
@JvmName("constantUnaryMinus")
override operator fun C.unaryMinus(): C = ring { -this@unaryMinus }
@JvmName("constantPlus")
override operator fun C.plus(other: C): C = ring { this@plus + other }
@JvmName("constantMinus")
override operator fun C.minus(other: C): C = ring { this@minus - other }
@JvmName("constantTimes")
override operator fun C.times(other: C): C = ring { this@times * other }
@JvmName("constantIsZero")
public override fun C.isZero(): Boolean = ring { this == zero }
@JvmName("constantIsNotZero")
public override fun C.isNotZero(): Boolean = ring { this != zero }
@JvmName("constantIsOne")
public override fun C.isOne(): Boolean = ring { this == one }
@JvmName("constantIsNotOne")
public override fun C.isNotOne(): Boolean = ring { this != one }
@JvmName("constantIsMinusOne")
public override fun C.isMinusOne(): Boolean = ring { this == -one }
@JvmName("constantIsNotMinusOne")
public override fun C.isNotMinusOne(): Boolean = ring { this != -one }
// endregion
// region Constant-polynomial relation
override operator fun C.plus(other: NumberedPolynomial<C>): NumberedPolynomial<C> =
if (this.isZero()) other
@ -521,7 +480,7 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
other.isZero() -> zero
else ->
NumberedPolynomial<C>(
buildCoefficients {
buildCoefficients(coefficients.size * other.coefficients.size) {
for ((degs1, c1) in coefficients) for ((degs2, c2) in other.coefficients) {
val degs =
(0..max(degs1.lastIndex, degs2.lastIndex))
@ -534,7 +493,6 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
}
public override fun NumberedPolynomial<C>.isZero(): Boolean = coefficients.values.all { it.isZero() }
public override fun NumberedPolynomial<C>.isNotZero(): Boolean = coefficients.values.any { it.isNotZero() }
public override fun NumberedPolynomial<C>.isOne(): Boolean =
with(coefficients) {
var foundAbsoluteTermAndItIsOne = false
@ -547,7 +505,6 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
}
foundAbsoluteTermAndItIsOne
}
public override fun NumberedPolynomial<C>.isNotOne(): Boolean = !isOne()
public override fun NumberedPolynomial<C>.isMinusOne(): Boolean =
with(coefficients) {
var foundAbsoluteTermAndItIsMinusOne = false
@ -560,7 +517,6 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
}
foundAbsoluteTermAndItIsMinusOne
}
public override fun NumberedPolynomial<C>.isNotMinusOne(): Boolean = !isMinusOne()
override val zero: NumberedPolynomial<C> = NumberedPolynomial<C>(emptyMap())
override val one: NumberedPolynomial<C> =
@ -572,7 +528,7 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
// TODO: Docs
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
override fun NumberedPolynomial<C>.equals(other: NumberedPolynomial<C>): Boolean =
override infix fun NumberedPolynomial<C>.equalsTo(other: NumberedPolynomial<C>): Boolean =
when {
this === other -> true
else -> coefficients.size == other.coefficients.size &&
@ -658,15 +614,9 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
public inline operator fun NumberedPolynomial<C>.invoke(argument: Map<Int, NumberedPolynomial<C>>): NumberedPolynomial<C> = this.substitute(ring, argument)
// endregion
// region Legacy
@Suppress("OVERRIDE_BY_INLINE", "NOTHING_TO_INLINE")
override inline fun add(left: NumberedPolynomial<C>, right: NumberedPolynomial<C>): NumberedPolynomial<C> = left + right
@Suppress("OVERRIDE_BY_INLINE", "NOTHING_TO_INLINE")
override inline fun multiply(left: NumberedPolynomial<C>, right: NumberedPolynomial<C>): NumberedPolynomial<C> = left * right
// endregion
// region Utilities
// TODO: Move to region internal utilities with context receiver
@JvmName("applyAndRemoveZerosInternal")
internal fun MutableMap<List<UInt>, C>.applyAndRemoveZeros(block: MutableMap<List<UInt>, C>.() -> Unit) : MutableMap<List<UInt>, C> {
contract {
callsInPlace(block, InvocationKind.EXACTLY_ONCE)
@ -678,12 +628,20 @@ public class NumberedPolynomialSpace<C, A : Ring<C>>(
internal fun Map<List<UInt>, C>.applyAndRemoveZeros(block: MutableMap<List<UInt>, C>.() -> Unit) : Map<List<UInt>, C> =
toMutableMap().applyAndRemoveZeros(block)
@OptIn(ExperimentalTypeInference::class)
internal fun buildCoefficients(@BuilderInference builderAction: MutableMap<List<UInt>, C>.() -> Unit): Map<List<UInt>, C> {
internal inline fun buildCoefficients(@BuilderInference builderAction: MutableMap<List<UInt>, C>.() -> Unit): Map<List<UInt>, C> {
contract { callsInPlace(builderAction, InvocationKind.EXACTLY_ONCE) }
return buildMap {
builderAction()
for ((degs, c) in this) if (c.isZero()) this.remove(degs)
}
}
@OptIn(ExperimentalTypeInference::class)
internal inline fun buildCoefficients(capacity: Int, @BuilderInference builderAction: MutableMap<List<UInt>, C>.() -> Unit): Map<List<UInt>, C> {
contract { callsInPlace(builderAction, InvocationKind.EXACTLY_ONCE) }
return buildMap(capacity) {
builderAction()
for ((degs, c) in this) if (c.isZero()) this.remove(degs)
}
}
// endregion
}

View File

@ -15,7 +15,7 @@ import kotlin.math.min
*
* @param coefficients constant is the leftmost coefficient.
*/
public class Polynomial<T>(public val coefficients: List<T>) : AbstractPolynomial<T> {
public data class Polynomial<T>(public val coefficients: List<T>) : AbstractPolynomial<T> {
override fun toString(): String = "Polynomial$coefficients"
}
@ -69,25 +69,8 @@ public fun <T> T.asPolynomial() : Polynomial<T> = Polynomial(listOf(this))
*/
@Suppress("INAPPLICABLE_JVM_NAME") // TODO: KT-31420
public open class PolynomialSpace<C, A : Ring<C>>(
public val ring: A,
) : AbstractPolynomialSpace<C, Polynomial<C>> {
// region Constant-integer relation
@JvmName("constantIntPlus")
public override operator fun C.plus(other: Int): C = ring { optimizedAddMultiplied(this@plus, one, other) }
@JvmName("constantIntMinus")
public override operator fun C.minus(other: Int): C = ring { optimizedAddMultiplied(this@minus, one, -other) }
@JvmName("constantIntTimes")
public override operator fun C.times(other: Int): C = ring { optimizedMultiply(this@times, other) }
// endregion
// region Integer-constant relation
@JvmName("intConstantPlus")
public override operator fun Int.plus(other: C): C = ring { optimizedAddMultiplied(other, one, this@plus) }
@JvmName("intConstantMinus")
public override operator fun Int.minus(other: C): C = ring { optimizedAddMultiplied(-other, one, this@minus) }
@JvmName("intConstantTimes")
public override operator fun Int.times(other: C): C = ring { optimizedMultiply(other, this@times) }
// endregion
public final override val ring: A,
) : AbstractPolynomialSpaceOverRing<C, Polynomial<C>, A> {
// region Polynomial-integer relation
public override operator fun Polynomial<C>.plus(other: Int): Polynomial<C> =
@ -179,29 +162,6 @@ public open class PolynomialSpace<C, A : Ring<C>>(
)
// endregion
// region Constant-constant relation
@JvmName("constantUnaryMinus")
public override operator fun C.unaryMinus(): C = ring { -this@unaryMinus }
@JvmName("constantPlus")
public override operator fun C.plus(other: C): C = ring { this@plus + other }
@JvmName("constantMinus")
public override operator fun C.minus(other: C): C = ring { this@minus - other }
@JvmName("constantTimes")
public override operator fun C.times(other: C): C = ring { this@times * other }
@JvmName("constantIsZero")
public override fun C.isZero(): Boolean = ring { this == zero }
@JvmName("constantIsNotZero")
public override fun C.isNotZero(): Boolean = ring { this != zero }
@JvmName("constantIsOne")
public override fun C.isOne(): Boolean = ring { this == one }
@JvmName("constantIsNotOne")
public override fun C.isNotOne(): Boolean = ring { this != one }
@JvmName("constantIsMinusOne")
public override fun C.isMinusOne(): Boolean = ring { this == -one }
@JvmName("constantIsNotMinusOne")
public override fun C.isNotMinusOne(): Boolean = ring { this != -one }
// endregion
// region Constant-polynomial relation
public override operator fun C.plus(other: Polynomial<C>): Polynomial<C> =
if (this.isZero()) other
@ -355,19 +315,16 @@ public open class PolynomialSpace<C, A : Ring<C>>(
}
public override fun Polynomial<C>.isZero(): Boolean = coefficients.all { it.isZero() }
public override fun Polynomial<C>.isNotZero(): Boolean = coefficients.any { it.isNotZero() }
public override fun Polynomial<C>.isOne(): Boolean =
with(coefficients) { isNotEmpty() && asSequence().withIndex().any { (index, c) -> if (index == 0) c.isOne() else c.isZero() } } // TODO: It's better to write new methods like `anyIndexed`. But what's better way to do it?
public override fun Polynomial<C>.isNotOne(): Boolean = !isOne()
public override fun Polynomial<C>.isMinusOne(): Boolean =
with(coefficients) { isNotEmpty() && asSequence().withIndex().any { (index, c) -> if (index == 0) c.isMinusOne() else c.isZero() } } // TODO: It's better to write new methods like `anyIndexed`. But what's better way to do it?
public override fun Polynomial<C>.isNotMinusOne(): Boolean = !isMinusOne()
override val zero: Polynomial<C> = Polynomial(emptyList())
override val one: Polynomial<C> = Polynomial(listOf(ring.one))
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
public override fun Polynomial<C>.equals(other: Polynomial<C>): Boolean =
public override infix fun Polynomial<C>.equalsTo(other: Polynomial<C>): Boolean =
when {
this === other -> true
else -> {

View File

@ -0,0 +1,355 @@
package space.kscience.kmath.functions
import space.kscience.kmath.operations.*
import kotlin.jvm.JvmName
import kotlin.math.max
import kotlin.math.min
public data class RationalFunction<C> internal constructor (
public override val numerator: Polynomial<C>,
public override val denominator: Polynomial<C>
) : AbstractRationalFunction<C, Polynomial<C>> {
override fun toString(): String = "RationalFunction${numerator.coefficients}/${denominator.coefficients}"
}
// region Internal utilities
/**
* Represents internal [RationalFunction] errors.
*/
internal class RationalFunctionError : Error {
constructor(): super()
constructor(message: String): super(message)
constructor(message: String?, cause: Throwable?): super(message, cause)
constructor(cause: Throwable?): super(cause)
}
/**
* Throws an [RationalFunction] with the given [message].
*/
internal fun rationalFunctionError(message: Any): Nothing = throw RationalFunctionError(message.toString())
// endregion
// region Constructors and converters
// Waiting for context receivers :( TODO: Replace with context receivers when they will be available
//context(RationalFunctionSpace<C, A>)
//@Suppress("FunctionName")
//internal fun <C, A: Ring<C>> RationalFunction(numerator: Polynomial<C>, denominator: Polynomial<C>): RationalFunction<C> =
// if (denominator.isZero()) throw ArithmeticException("/ by zero")
// else RationalFunction<C>(numerator, denominator)
//context(RationalFunctionSpace<C, A>)
//@Suppress("FunctionName")
//public fun <C, A: Ring<C>> RationalFunction(numeratorCoefficients: List<C>, denominatorCoefficients: List<C>, reverse: Boolean = false): RationalFunction<C> =
// RationalFunction<C>(
// Polynomial( with(numeratorCoefficients) { if (reverse) reversed() else this } ),
// Polynomial( with(denominatorCoefficients) { if (reverse) reversed() else this } ).also { if (it.isZero()) }
// )
//context(RationalFunctionSpace<C, A>)
//@Suppress("FunctionName")
//public fun <C, A: Ring<C>> RationalFunction(numerator: Polynomial<C>): RationalFunction<C> =
// RationalFunction(numerator, onePolynomial)
//context(RationalFunctionSpace<C, A>)
//@Suppress("FunctionName")
//public fun <C, A: Ring<C>> RationalFunction(numeratorCoefficients: List<C>, reverse: Boolean = false): RationalFunction<C> =
// RationalFunction(
// Polynomial( with(numeratorCoefficients) { if (reverse) reversed() else this } )
// )
// endregion
public class RationalFunctionSpace<C, A : Ring<C>> (
public val ring: A,
) : AbstractRationalFunctionalSpaceOverPolynomialSpace<C, Polynomial<C>, RationalFunction<C>, A> {
override val polynomialRing : PolynomialSpace<C, A> = PolynomialSpace(ring)
// region Rational-integer relation
/**
* Returns sum of the rational function and the integer represented as rational function.
*
* The operation is equivalent to adding [other] copies of unit polynomial to [this].
*/
public override operator fun RationalFunction<C>.plus(other: Int): RationalFunction<C> =
RationalFunction(
numerator + denominator * other,
denominator
)
/**
* Returns difference between the rational function and the integer represented as rational function.
*
* The operation is equivalent to subtraction [other] copies of unit polynomial from [this].
*/
public override operator fun RationalFunction<C>.minus(other: Int): RationalFunction<C> =
RationalFunction(
numerator - denominator * other,
denominator
)
/**
* Returns product of the rational function and the integer represented as rational function.
*
* The operation is equivalent to sum of [other] copies of [this].
*/
public override operator fun RationalFunction<C>.times(other: Int): RationalFunction<C> =
RationalFunction(
numerator * other,
denominator
)
// endregion
// region Integer-Rational relation
/**
* Returns sum of the integer represented as rational function and the rational function.
*
* The operation is equivalent to adding [this] copies of unit polynomial to [other].
*/
public override operator fun Int.plus(other: RationalFunction<C>): RationalFunction<C> = TODO()
/**
* Returns difference between the integer represented as rational function and the rational function.
*
* The operation is equivalent to subtraction [this] copies of unit polynomial from [other].
*/
public override operator fun Int.minus(other: RationalFunction<C>): RationalFunction<C> = TODO()
/**
* Returns product of the integer represented as rational function and the rational function.
*
* The operation is equivalent to sum of [this] copies of [other].
*/
public override operator fun Int.times(other: RationalFunction<C>): RationalFunction<C> = TODO()
// endregion
// region Constant-rational relation
/**
* Returns sum of the constant represented as rational function and the rational function.
*/
public override operator fun C.plus(other: RationalFunction<C>): RationalFunction<C> = TODO()
/**
* Returns difference between the constant represented as polynomial and the rational function.
*/
public override operator fun C.minus(other: RationalFunction<C>): RationalFunction<C> = TODO()
/**
* Returns product of the constant represented as polynomial and the rational function.
*/
public override operator fun C.times(other: RationalFunction<C>): RationalFunction<C> = TODO()
// endregion
// region Rational-constant relation
/**
* Returns sum of the constant represented as rational function and the rational function.
*/
public override operator fun RationalFunction<C>.plus(other: C): RationalFunction<C> =
RationalFunction(
numerator + denominator * other,
denominator
)
/**
* Returns difference between the constant represented as rational function and the rational function.
*/
public override operator fun RationalFunction<C>.minus(other: C): RationalFunction<C> =
RationalFunction(
numerator - denominator * other,
denominator
)
/**
* Returns product of the constant represented as rational function and the rational function.
*/
public override operator fun RationalFunction<C>.times(other: C): RationalFunction<C> =
RationalFunction(
numerator * other,
denominator
)
// endregion
// region Polynomial-rational relation
/**
* Returns sum of the polynomial represented as rational function and the rational function.
*/
public override operator fun Polynomial<C>.plus(other: RationalFunction<C>): RationalFunction<C> = TODO()
/**
* Returns difference between the polynomial represented as polynomial and the rational function.
*/
public override operator fun Polynomial<C>.minus(other: RationalFunction<C>): RationalFunction<C> = TODO()
/**
* Returns product of the polynomial represented as polynomial and the rational function.
*/
public override operator fun Polynomial<C>.times(other: RationalFunction<C>): RationalFunction<C> = TODO()
// endregion
// region Rational-polynomial relation
/**
* Returns sum of the polynomial represented as rational function and the rational function.
*/
public override operator fun RationalFunction<C>.plus(other: Polynomial<C>): RationalFunction<C> =
RationalFunction(
numerator + denominator * other,
denominator
)
/**
* Returns difference between the polynomial represented as rational function and the rational function.
*/
public override operator fun RationalFunction<C>.minus(other: Polynomial<C>): RationalFunction<C> =
RationalFunction(
numerator - denominator * other,
denominator
)
/**
* Returns product of the polynomial represented as rational function and the rational function.
*/
public override operator fun RationalFunction<C>.times(other: Polynomial<C>): RationalFunction<C> =
RationalFunction(
numerator * other,
denominator
)
// endregion
// region Rational-rational relation
/**
* Returns negation of the rational function.
*/
public override operator fun RationalFunction<C>.unaryMinus(): RationalFunction<C> = RationalFunction(-numerator, denominator)
/**
* Returns sum of the rational functions.
*/
public override operator fun RationalFunction<C>.plus(other: RationalFunction<C>): RationalFunction<C> =
RationalFunction(
numerator * other.denominator + denominator * other.numerator,
denominator * other.denominator
)
/**
* Returns difference of the rational functions.
*/
public override operator fun RationalFunction<C>.minus(other: RationalFunction<C>): RationalFunction<C> =
RationalFunction(
numerator * other.denominator - denominator * other.numerator,
denominator * other.denominator
)
/**
* Returns product of the rational functions.
*/
public override operator fun RationalFunction<C>.times(other: RationalFunction<C>): RationalFunction<C> =
RationalFunction(
numerator * other.numerator,
denominator * other.denominator
)
/**
* Check if the instant is zero rational function.
*/
public override fun RationalFunction<C>.isZero(): Boolean = numerator.isZero()
/**
* Check if the instant is unit rational function.
*/
public override fun RationalFunction<C>.isOne(): Boolean = numerator.equalsTo(denominator)
/**
* Check if the instant is minus unit rational function.
*/
public override fun RationalFunction<C>.isMinusOne(): Boolean = (numerator + denominator).isZero()
/**
* Instance of zero rational function (zero of the rational functions ring).
*/
public override val zero: RationalFunction<C> = RationalFunction(polynomialZero, polynomialOne)
/**
* Instance of unit polynomial (unit of the rational functions ring).
*/
public override val one: RationalFunction<C> = RationalFunction(polynomialOne, polynomialOne)
/**
* Checks equality of the rational functions.
*/
@Suppress("EXTENSION_SHADOWED_BY_MEMBER", "CovariantEquals")
public override infix fun RationalFunction<C>.equalsTo(other: RationalFunction<C>): Boolean =
when {
this === other -> true
numeratorDegree - denominatorDegree != with(other) { numeratorDegree - denominatorDegree } -> false
else -> numerator * other.denominator equalsTo other.numerator * denominator
}
// endregion
// region REST TODO: Разобрать
public operator fun RationalFunction<C>.div(other: RationalFunction<C>): RationalFunction<C> =
RationalFunction(
numerator * other.denominator,
denominator * other.numerator
)
public operator fun RationalFunction<C>.div(other: Polynomial<C>): RationalFunction<C> =
RationalFunction(
numerator,
denominator * other
)
public operator fun RationalFunction<C>.div(other: C): RationalFunction<C> =
RationalFunction(
numerator,
denominator * other
)
public operator fun RationalFunction<C>.div(other: Int): RationalFunction<C> =
RationalFunction(
numerator,
denominator * other
)
// operator fun invoke(arg: UnivariatePolynomial<T>): RationalFunction<T> =
// RationalFunction(
// numerator(arg),
// denominator(arg)
// )
//
// operator fun invoke(arg: RationalFunction<T>): RationalFunction<T> {
// val num = numerator invokeRFTakeNumerator arg
// val den = denominator invokeRFTakeNumerator arg
// val degreeDif = numeratorDegree - denominatorDegree
// return if (degreeDif > 0)
// RationalFunction(
// num,
// multiplyByPower(den, arg.denominator, degreeDif)
// )
// else
// RationalFunction(
// multiplyByPower(num, arg.denominator, -degreeDif),
// den
// )
// }
//
// override fun toString(): String = toString(UnivariatePolynomial.variableName)
//
// fun toString(withVariableName: String = UnivariatePolynomial.variableName): String =
// when(true) {
// numerator.isZero() -> "0"
// denominator.isOne() -> numerator.toString(withVariableName)
// else -> "${numerator.toStringWithBrackets(withVariableName)}/${denominator.toStringWithBrackets(withVariableName)}"
// }
//
// fun toStringWithBrackets(withVariableName: String = UnivariatePolynomial.variableName): String =
// when(true) {
// numerator.isZero() -> "0"
// denominator.isOne() -> numerator.toStringWithBrackets(withVariableName)
// else -> "(${numerator.toStringWithBrackets(withVariableName)}/${denominator.toStringWithBrackets(withVariableName)})"
// }
//
// fun toReversedString(withVariableName: String = UnivariatePolynomial.variableName): String =
// when(true) {
// numerator.isZero() -> "0"
// denominator.isOne() -> numerator.toReversedString(withVariableName)
// else -> "${numerator.toReversedStringWithBrackets(withVariableName)}/${denominator.toReversedStringWithBrackets(withVariableName)}"
// }
//
// fun toReversedStringWithBrackets(withVariableName: String = UnivariatePolynomial.variableName): String =
// when(true) {
// numerator.isZero() -> "0"
// denominator.isOne() -> numerator.toReversedStringWithBrackets(withVariableName)
// else -> "(${numerator.toReversedStringWithBrackets(withVariableName)}/${denominator.toReversedStringWithBrackets(withVariableName)})"
// }
//
// fun removeZeros() =
// RationalFunction(
// numerator.removeZeros(),
// denominator.removeZeros()
// )
// endregion
}

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@ -0,0 +1,34 @@
package space.kscience.kmath.functions
// region Operator extensions
// region Field case
//operator fun <T: Field<T>> RationalFunction<T>.invoke(arg: T): T = numerator(arg) / denominator(arg)
//
//fun <T: Field<T>> RationalFunction<T>.reduced(): RationalFunction<T> =
// polynomialGCD(numerator, denominator).let {
// RationalFunction(
// numerator / it,
// denominator / it
// )
// }
// endregion
// endregion
// region Derivatives
///**
// * Returns result of applying formal derivative to the polynomial.
// *
// * @param T Field where we are working now.
// * @return Result of the operator.
// */
//fun <T: Ring<T>> RationalFunction<T>.derivative() =
// RationalFunction(
// numerator.derivative() * denominator - denominator.derivative() * numerator,
// denominator * denominator
// )
// endregion