multiplication.cpp
29 KB
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#include <poincare/multiplication.h>
#include <poincare/addition.h>
#include <poincare/arithmetic.h>
#include <poincare/division.h>
#include <poincare/matrix.h>
#include <poincare/opposite.h>
#include <poincare/parenthesis.h>
#include <poincare/power.h>
#include <poincare/rational.h>
#include <poincare/simplification_root.h>
#include <poincare/subtraction.h>
#include <poincare/tangent.h>
#include <poincare/undefined.h>
#include <cmath>
#include <ion.h>
extern "C" {
#include <assert.h>
#include <stdlib.h>
}
namespace Poincare {
Expression::Type Multiplication::type() const {
return Expression::Type::Multiplication;
}
Expression * Multiplication::clone() const {
if (numberOfOperands() == 0) {
return new Multiplication();
}
return new Multiplication(operands(), numberOfOperands(), true);
}
int Multiplication::polynomialDegree(char symbolName) const {
int degree = 0;
for (int i = 0; i < numberOfOperands(); i++) {
int d = operand(i)->polynomialDegree(symbolName);
if (d < 0) {
return -1;
}
degree += d;
}
return degree;
}
int Multiplication::privateGetPolynomialCoefficients(char symbolName, Expression * coefficients[]) const {
int deg = polynomialDegree(symbolName);
if (deg < 0 || deg > k_maxPolynomialDegree) {
return -1;
}
// Initialization of coefficients
for (int i = 1; i <= deg; i++) {
coefficients[i] = new Rational(0);
}
coefficients[0] = new Rational(1);
Expression * intermediateCoefficients[k_maxNumberOfPolynomialCoefficients];
// Let's note result = a(0)+a(1)*X+a(2)*X^2+a(3)*x^3+..
for (int i = 0; i < numberOfOperands(); i++) {
// operand(i) = b(0)+b(1)*X+b(2)*X^2+b(3)*x^3+...
int degI = operand(i)->privateGetPolynomialCoefficients(symbolName, intermediateCoefficients);
assert(degI <= k_maxPolynomialDegree);
for (int j = deg; j > 0; j--) {
// new coefficients[j] = b(0)*a(j)+b(1)*a(j-1)+b(2)*a(j-2)+...
Addition * a = new Addition();
int jbis = j > degI ? degI : j;
for (int l = 0; l <= jbis ; l++) {
// Always copy the a and b coefficients are they are used multiple times
a->addOperand(new Multiplication(intermediateCoefficients[l], coefficients[j-l], true));
}
/* a(j) and b(j) are used only to compute coefficient at rank >= j, we
* can delete them as we compute new coefficient by decreasing ranks. */
delete coefficients[j];
if (j <= degI) { delete intermediateCoefficients[j]; };
coefficients[j] = a;
}
// new coefficients[0] = a(0)*b(0)
coefficients[0] = new Multiplication(coefficients[0], intermediateCoefficients[0], false);
}
return deg;
}
bool Multiplication::needParenthesisWithParent(const Expression * e) const {
Type types[] = {Type::Division, Type::Power, Type::Factorial};
return e->isOfType(types, 3);
}
ExpressionLayout * Multiplication::createLayout(PrintFloat::Mode floatDisplayMode, int numberOfSignificantDigits) const {
const char middleDotString[] = {Ion::Charset::MiddleDot, 0};
return LayoutEngine::createInfixLayout(this, floatDisplayMode, numberOfSignificantDigits, middleDotString);
}
int Multiplication::writeTextInBuffer(char * buffer, int bufferSize, PrintFloat::Mode floatDisplayMode, int numberOfSignificantDigits) const {
const char multiplicationString[] = {Ion::Charset::MultiplicationSign, 0};
return LayoutEngine::writeInfixExpressionTextInBuffer(this, buffer, bufferSize, floatDisplayMode, numberOfSignificantDigits, multiplicationString);
}
Expression::Sign Multiplication::sign() const {
int sign = 1;
for (int i = 0; i < numberOfOperands(); i++) {
sign *= (int)operand(i)->sign();
}
return (Sign)sign;
}
Expression * Multiplication::setSign(Sign s, Context & context, AngleUnit angleUnit) {
assert(s == Sign::Positive);
for (int i = 0; i < numberOfOperands(); i++) {
if (operand(i)->sign() == Sign::Negative) {
editableOperand(i)->setSign(s, context, angleUnit);
}
}
return shallowReduce(context, angleUnit);
}
template<typename T>
std::complex<T> Multiplication::compute(const std::complex<T> c, const std::complex<T> d) {
return c*d;
}
template<typename T>
MatrixComplex<T> Multiplication::computeOnMatrices(const MatrixComplex<T> m, const MatrixComplex<T> n) {
if (m.numberOfColumns() != n.numberOfRows()) {
return MatrixComplex<T>::Undefined();
}
std::complex<T> * operands = new std::complex<T> [m.numberOfRows()*n.numberOfColumns()];
for (int i = 0; i < m.numberOfRows(); i++) {
for (int j = 0; j < n.numberOfColumns(); j++) {
std::complex<T> c(0.0);
for (int k = 0; k < m.numberOfColumns(); k++) {
c += m.complexOperand(i*m.numberOfColumns()+k)*n.complexOperand(k*n.numberOfColumns()+j);
}
operands[i*n.numberOfColumns()+j] = c;
}
}
MatrixComplex<T> result = MatrixComplex<T>(operands, m.numberOfRows(), n.numberOfColumns());
delete[] operands;
return result;
}
template<typename T>
void Multiplication::computeOnArrays(T * m, T * n, T * result, int mNumberOfColumns, int mNumberOfRows, int nNumberOfColumns) {
for (int i = 0; i < mNumberOfRows; i++) {
for (int j = 0; j < nNumberOfColumns; j++) {
T res = 0.0f;
for (int k = 0; k < mNumberOfColumns; k++) {
res+= m[i*mNumberOfColumns+k]*n[k*nNumberOfColumns+j];
}
result[i*nNumberOfColumns+j] = res;
}
}
}
bool Multiplication::HaveSameNonRationalFactors(const Expression * e1, const Expression * e2) {
int numberOfNonRationalFactors1 = e1->operand(0)->type() == Type::Rational ? e1->numberOfOperands()-1 : e1->numberOfOperands();
int numberOfNonRationalFactors2 = e2->operand(0)->type() == Type::Rational ? e2->numberOfOperands()-1 : e2->numberOfOperands();
if (numberOfNonRationalFactors1 != numberOfNonRationalFactors2) {
return false;
}
int firstNonRationalOperand1 = e1->operand(0)->type() == Type::Rational ? 1 : 0;
int firstNonRationalOperand2 = e2->operand(0)->type() == Type::Rational ? 1 : 0;
for (int i = 0; i < numberOfNonRationalFactors1; i++) {
if (!(e1->operand(firstNonRationalOperand1+i)->isIdenticalTo(e2->operand(firstNonRationalOperand2+i)))) {
return false;
}
}
return true;
}
static inline const Expression * Base(const Expression * e) {
if (e->type() == Expression::Type::Power) {
return e->operand(0);
}
return e;
}
Expression * Multiplication::shallowReduce(Context& context, AngleUnit angleUnit) {
return privateShallowReduce(context, angleUnit, true, true);
}
Expression * Multiplication::privateShallowReduce(Context & context, AngleUnit angleUnit, bool shouldExpand, bool canBeInterrupted) {
Expression * e = Expression::shallowReduce(context, angleUnit);
if (e != this) {
return e;
}
/* Step 1: Multiplication is associative, so let's start by merging children
* which also are multiplications themselves. */
mergeMultiplicationOperands();
/* Step 2: If any of the operand is zero, the multiplication result is zero */
for (int i = 0; i < numberOfOperands(); i++) {
const Expression * o = operand(i);
if (o->type() == Type::Rational && static_cast<const Rational *>(o)->isZero()) {
return replaceWith(new Rational(0), true);
}
}
// Step 3: Sort the operands
sortOperands(SimplificationOrder, canBeInterrupted);
#if MATRIX_EXACT_REDUCING
/* Step 3bis: get rid of matrix */
int n = 1;
int m = 1;
/* All operands have been simplified so if any operand contains a matrix, it
* is at the root node of the operand. Moreover, thanks to the simplification
* order, all matrix operands (if any) are the last operands. */
Expression * lastOperand = editableOperand(numberOfOperands()-1);
if (lastOperand->type() == Type::Matrix) {
Matrix * resultMatrix = static_cast<Matrix *>(lastOperand);
// Use the last matrix operand as the final matrix
n = resultMatrix->numberOfRows();
m = resultMatrix->numberOfColumns();
/* Scan accross the multiplication operands to find any other matrix:
* (the last operand is the result matrix so we start at
* numberOfOperands()-2)*/
int k = numberOfOperands()-2;
while (k >= 0 && operand(k)->type() == Type::Matrix) {
Matrix * currentMatrix = static_cast<Matrix *>(editableOperand(k));
int on = currentMatrix->numberOfRows();
int om = currentMatrix->numberOfColumns();
if (om != n) {
return replaceWith(new Undefined(), true);
}
// Create the matrix resulting of the multiplication of the current matrix and the result matrix
/* resultMatrix
* i2= 0..m
* +-+-+-+-+-+
* | |ย |ย |ย |ย |
* +-+-+-+-+-+
* j=0..n | |ย |ย |ย |ย |
* +-+-+-+-+-+
* | |ย |ย |ย | |
* +-+-+-+-+-+
* currentMatrix
* j=0..om
* +---+---+---+ +-+-+-+-+-+
* | ย |ย ย | ย | | | | | | |
* +---+---+---+ +-+-+-+-+-+
*i1=0..on | ย |ย ย |ย | | |e| | | |
* +---+---+---+ +-+-+-+-+-+
* | ย |ย ย | | | | | | | |
* +---+---+---+ +-+-+-+-+-+
* */
Expression ** newMatrixOperands = new Expression * [on*m];
for (int e = 0; e < on*m; e++) {
newMatrixOperands[e] = new Addition();
int i2 = e%m;
int i1 = e/m;
for (int j = 0; j < n; j++) {
Expression * mult = new Multiplication(currentMatrix->editableOperand(j+om*i1), resultMatrix->editableOperand(j*m+i2), true);
static_cast<Addition *>(newMatrixOperands[e])->addOperand(mult);
mult->shallowReduce(context, angleUnit);
}
Reduce(&newMatrixOperands[e], context, angleUnit, false);
}
n = on;
removeOperand(currentMatrix, true);
resultMatrix = static_cast<Matrix *>(resultMatrix->replaceWith(new Matrix(newMatrixOperands, n, m, false), true));
k--;
}
removeOperand(resultMatrix, false);
// Distribute the remaining multiplication on matrix operands
for (int i = 0; i < n*m; i++) {
Multiplication * m = static_cast<Multiplication *>(clone());
Expression * entryI = resultMatrix->editableOperand(i);
resultMatrix->replaceOperand(entryI, m, false);
m->addOperand(entryI);
m->shallowReduce(context, angleUnit);
}
return replaceWith(resultMatrix, true)->shallowReduce(context, angleUnit);
}
#endif
/* Step 4: Gather like terms. For example, turn pi^2*pi^3 into pi^5. Thanks to
* the simplification order, such terms are guaranteed to be next to each
* other. */
int i = 0;
while (i < numberOfOperands()-1) {
Expression * oi = editableOperand(i);
Expression * oi1 = editableOperand(i+1);
if (TermsHaveIdenticalBase(oi, oi1)) {
bool shouldFactorizeBase = true;
if (TermHasRationalBase(oi)) {
/* Combining powers of a given rational isn't straightforward. Indeed,
* there are two cases we want to deal with:
* - 2*2^(1/2) or 2*2^pi, we want to keep as-is
* - 2^(1/2)*2^(3/2) we want to combine. */
shouldFactorizeBase = oi->type() == Type::Power && oi1->type() == Type::Power;
}
if (shouldFactorizeBase) {
factorizeBase(oi, oi1, context, angleUnit);
continue;
}
} else if (TermHasRationalBase(oi) && TermHasRationalBase(oi1) && TermsHaveIdenticalExponent(oi, oi1)) {
factorizeExponent(oi, oi1, context, angleUnit);
continue;
}
i++;
}
/* Step 5: We look for terms of form sin(x)^p*cos(x)^q with p, q rational of
*opposite signs. We replace them by either:
* - tan(x)^p*cos(x)^(p+q) if |p|<|q|
* - tan(x)^(-q)*sin(x)^(p+q) otherwise */
for (int i = 0; i < numberOfOperands(); i++) {
Expression * o1 = editableOperand(i);
if (Base(o1)->type() == Type::Sine && TermHasRationalExponent(o1)) {
const Expression * x = Base(o1)->operand(0);
/* Thanks to the SimplificationOrder, Cosine-base factors are after
* Sine-base factors */
for (int j = i+1; j < numberOfOperands(); j++) {
Expression * o2 = editableOperand(j);
if (Base(o2)->type() == Type::Cosine && TermHasRationalExponent(o2) && Base(o2)->operand(0)->isIdenticalTo(x)) {
factorizeSineAndCosine(o1, o2, context, angleUnit);
break;
}
}
}
}
/* Replacing sin/cos by tan factors may have mixed factors and factors are
* guaranteed to be sorted (according ot SimplificationOrder) at the end of
* shallowReduce */
sortOperands(SimplificationOrder, true);
/* Step 6: We remove rational operands that appeared in the middle of sorted
* operands. It's important to do this after having factorized because
* factorization can lead to new ones. Indeed:
* pi^(-1)*pi-> 1
* i*i -> -1
* 2^(1/2)*2^(1/2) -> 2
* sin(x)*cos(x) -> 1*tan(x)
* Last, we remove the only rational operand if it is one and not the only
* operand. */
i = 1;
while (i < numberOfOperands()) {
Expression * o = editableOperand(i);
if (o->type() == Type::Rational && static_cast<Rational *>(o)->isOne()) {
removeOperand(o, true);
continue;
}
if (o->type() == Type::Rational) {
if (operand(0)->type() == Type::Rational) {
Rational * o0 = static_cast<Rational *>(editableOperand(0));
Rational m = Rational::Multiplication(*o0, *(static_cast<Rational *>(o)));
replaceOperand(o0, new Rational(m), true);
removeOperand(o, true);
} else {
removeOperand(o, false);
addOperandAtIndex(o, 0);
}
continue;
}
i++;
}
if (operand(0)->type() == Type::Rational && static_cast<Rational *>(editableOperand(0))->isOne() && numberOfOperands() > 1) {
removeOperand(editableOperand(0), true);
}
/* Step 7: Expand multiplication over addition operands if any. For example,
* turn (a+b)*c into a*c + b*c. We do not want to do this step right now if
* the parent is a multiplication to avoid missing factorization such as
* (x+y)^(-1)*((a+b)*(x+y)).
* Note: This step must be done after Step 4, otherwise we wouldn't be able to
* reduce expressions such as (x+y)^(-1)*(x+y)(a+b). */
if (shouldExpand && parent()->type() != Type::Multiplication) {
for (int i=0; i<numberOfOperands(); i++) {
if (operand(i)->type() == Type::Addition) {
return distributeOnOperandAtIndex(i, context, angleUnit);
}
}
}
// Step 8: Let's remove the multiplication altogether if it has one operand
Expression * result = squashUnaryHierarchy();
return result;
}
void Multiplication::mergeMultiplicationOperands() {
// Multiplication is associative: a*(b*c)->a*b*c
int i = 0;
int initialNumberOfOperands = numberOfOperands();
while (i < initialNumberOfOperands) {
Expression * o = editableOperand(i);
if (o->type() == Type::Multiplication) {
mergeOperands(static_cast<Multiplication *>(o)); // TODO: ensure that matrix operands are not swapped to implement MATRIX_EXACT_REDUCING
continue;
}
i++;
}
}
void Multiplication::factorizeSineAndCosine(Expression * o1, Expression * o2, Context & context, AngleUnit angleUnit) {
assert(o1->parent() == this && o2->parent() == this);
/* This function turn sin(x)^p * cos(x)^q into either:
* - tan(x)^p*cos(x)^(p+q) if |p|<|q|
* - tan(x)^(-q)*sin(x)^(p+q) otherwise */
const Expression * x = Base(o1)->operand(0);
Rational p = o1->type() == Type::Power ? *(static_cast<Rational *>(o1->editableOperand(1))) : Rational(1);
Rational q = o2->type() == Type::Power ? *(static_cast<Rational *>(o2->editableOperand(1))) : Rational(1);
/* If p and q have the same sign, we cannot replace them by a tangent */
if ((int)p.sign()*(int)q.sign() > 0) {
return;
}
Rational sumPQ = Rational::Addition(p, q);
Rational absP = p;
absP.setSign(Sign::Positive);
Rational absQ = q;
absQ.setSign(Sign::Positive);
Expression * tan = new Tangent(x, true);
if (Rational::NaturalOrder(absP, absQ) < 0) {
if (o1->type() == Type::Power) {
o1->replaceOperand(o1->operand(0), tan, true);
} else {
replaceOperand(o1, tan, true);
o1 = tan;
}
o1->shallowReduce(context, angleUnit);
if (o2->type() == Type::Power) {
o2->replaceOperand(o2->operand(1), new Rational(sumPQ), true);
} else {
Expression * newO2 = new Power(o2, new Rational(sumPQ), false);
replaceOperand(o2, newO2, false);
o2 = newO2;
}
o2->shallowReduce(context, angleUnit);
} else {
if (o2->type() == Type::Power) {
o2->replaceOperand(o2->operand(1), new Rational(Rational::Multiplication(q, Rational(-1))), true);
o2->replaceOperand(o2->operand(0), tan, true);
} else {
Expression * newO2 = new Power(tan, new Rational(-1), false);
replaceOperand(o2, newO2, true);
o2 = newO2;
}
o2->shallowReduce(context, angleUnit);
if (o1->type() == Type::Power) {
o1->replaceOperand(o1->operand(1), new Rational(sumPQ), true);
} else {
Expression * newO1 = new Power(o1, new Rational(sumPQ), false);
replaceOperand(o1, newO1, false);
o1 = newO1;
}
o1->shallowReduce(context, angleUnit);
}
}
void Multiplication::factorizeBase(Expression * e1, Expression * e2, Context & context, AngleUnit angleUnit) {
/* This function factorizes two operands which have a common base. For example
* if this is Multiplication(pi^2, pi^3), then pi^2 and pi^3 could be merged
* and this turned into Multiplication(pi^5). */
assert(TermsHaveIdenticalBase(e1, e2));
// Step 1: Find the new exponent
Expression * s = new Addition(CreateExponent(e1), CreateExponent(e2), false);
// Step 2: Get rid of one of the operands
removeOperand(e2, true);
// Step 3: Use the new exponent
Power * p = nullptr;
if (e1->type() == Type::Power) {
// If e1 is a power, replace the initial exponent with the new one
e1->replaceOperand(e1->operand(1), s, true);
p = static_cast<Power *>(e1);
} else {
// Otherwise, create a new Power node
p = new Power(e1, s, false);
replaceOperand(e1, p, false);
}
// Step 4: Reduce the new power
s->shallowReduce(context, angleUnit); // pi^2*pi^3 -> pi^(2+3) -> pi^5
Expression * reducedP = p->shallowReduce(context, angleUnit); // pi^2*pi^-2 -> pi^0 -> 1
/* Step 5: Reducing the new power might have turned it into a multiplication,
* ie: 12^(1/2) -> 2*3^(1/2). In that case, we need to merge the multiplication
* node with this. */
if (reducedP->type() == Type::Multiplication) {
mergeMultiplicationOperands();
}
}
void Multiplication::factorizeExponent(Expression * e1, Expression * e2, Context & context, AngleUnit angleUnit) {
/* This function factorizes operands which share a common exponent. For
* example, it turns Multiplication(2^x,3^x) into Multiplication(6^x). */
assert(e1->parent() == this && e2->parent() == this);
const Expression * base1 = e1->operand(0)->clone();
const Expression * base2 = e2->operand(0);
e2->detachOperand(base2);
Expression * m = new Multiplication(base1, base2, false);
removeOperand(e2, true);
e1->replaceOperand(e1->operand(0), m, true);
m->shallowReduce(context, angleUnit); // 2^x*3^x -> (2*3)^x -> 6^x
Expression * reducedE1 = e1->shallowReduce(context, angleUnit); // 2^x*(1/2)^x -> (2*1/2)^x -> 1
/* Reducing the new power might have turned it into a multiplication,
* ie: 12^(1/2) -> 2*3^(1/2). In that case, we need to merge the multiplication
* node with this. */
if (reducedE1->type() == Type::Multiplication) {
mergeMultiplicationOperands();
}
}
Expression * Multiplication::distributeOnOperandAtIndex(int i, Context & context, AngleUnit angleUnit) {
// This function turns a*(b+c) into a*b + a*c
// We avoid deleting and creating a new addition
Addition * a = static_cast<Addition *>(editableOperand(i));
removeOperand(a, false);
for (int j = 0; j < a->numberOfOperands(); j++) {
Multiplication * m = static_cast<Multiplication *>(clone());
Expression * termJ = a->editableOperand(j);
a->replaceOperand(termJ, m, false);
m->addOperand(termJ);
m->shallowReduce(context, angleUnit); // pi^(-1)*(pi + x) -> pi^(-1)*pi + pi^(-1)*x -> 1 + pi^(-1)*x
}
replaceWith(a, true);
return a->shallowReduce(context, angleUnit); // Order terms, put under a common denominator if needed
}
const Expression * Multiplication::CreateExponent(Expression * e) {
return e->type() == Type::Power ? e->operand(1)->clone() : new Rational(1);
}
bool Multiplication::TermsHaveIdenticalBase(const Expression * e1, const Expression * e2) {
return Base(e1)->isIdenticalTo(Base(e2));
}
bool Multiplication::TermsHaveIdenticalExponent(const Expression * e1, const Expression * e2) {
/* Note: We will return false for e1=2 and e2=Pi, even though one could argue
* that these have the same exponent whose value is 1. */
return e1->type() == Type::Power && e2->type() == Type::Power && (e1->operand(1)->isIdenticalTo(e2->operand(1)));
}
bool Multiplication::TermHasRationalBase(const Expression * e) {
return Base(e)->type() == Type::Rational;
}
bool Multiplication::TermHasRationalExponent(const Expression * e) {
if (e->type() != Type::Power) {
return true;
}
if (e->operand(1)->type() == Type::Rational) {
return true;
}
return false;
}
Expression * Multiplication::shallowBeautify(Context & context, AngleUnit angleUnit) {
/* Beautifying a Multiplication consists in several possible operations:
* - Add Opposite ((-3)*x -> -(3*x), useful when printing fractions)
* - Adding parenthesis if needed (a*(b+c) is not a*b+c)
* - Creating a Division if there's either a term with a power of -1 (a.b^(-1)
* shall become a/b) or a non-integer rational term (3/2*a -> (3*a)/2). */
// Step 1: Turn -n*A into -(n*A)
if (operand(0)->type() == Type::Rational && operand(0)->sign() == Sign::Negative) {
if (static_cast<const Rational *>(operand(0))->isMinusOne()) {
removeOperand(editableOperand(0), true);
} else {
editableOperand(0)->setSign(Sign::Positive, context, angleUnit);
}
Expression * e = squashUnaryHierarchy();
Opposite * o = new Opposite(e, true);
e->replaceWith(o, true);
o->editableOperand(0)->shallowBeautify(context, angleUnit);
return o;
}
/* Step 2: Merge negative powers: a*b^(-1)*c^(-pi)*d = a*(b*c^pi)^(-1)
* This also turns 2/3*a into 2*a*3^(-1) */
Expression * e = mergeNegativePower(context, angleUnit);
if (e->type() == Type::Power) {
return e->shallowBeautify(context, angleUnit);
}
assert(e == this);
// Step 3: Add Parenthesis if needed
for (int i = 0; i < numberOfOperands(); i++) {
const Expression * o = operand(i);
if (o->type() == Type::Addition ) {
Parenthesis * p = new Parenthesis(o, false);
replaceOperand(o, p, false);
}
}
// Step 4: Create a Division if needed
for (int i = 0; i < numberOfOperands(); i++) {
if (!(operand(i)->type() == Type::Power && operand(i)->operand(1)->type() == Type::Rational && static_cast<const Rational *>(operand(i)->operand(1))->isMinusOne())) {
continue;
}
// Let's remove the denominator-to-be from this
Power * p = static_cast<Power *>(editableOperand(i));
Expression * denominatorOperand = p->editableOperand(0);
p->detachOperand(denominatorOperand);
removeOperand(p, true);
Expression * numeratorOperand = shallowReduce(context, angleUnit);
// Delete parenthesis unnecessary on numerator
if (numeratorOperand->type() == Type::Parenthesis) {
numeratorOperand = numeratorOperand->replaceWith(numeratorOperand->editableOperand(0), true);
}
Expression * originalParent = numeratorOperand->parent();
Division * d = new Division(numeratorOperand, denominatorOperand, false);
originalParent->replaceOperand(numeratorOperand, d, false);
return d->shallowBeautify(context, angleUnit);
}
return this;
}
Expression * Multiplication::cloneDenominator(Context & context, AngleUnit angleUnit) const {
// Merge negative power: a*b^-1*c^(-Pi)*d = a*(b*c^Pi)^-1
// WARNING: we do not want to change the expression but to create a new one.
SimplificationRoot root(clone());
Expression * e = ((Multiplication *)root.operand(0))->mergeNegativePower(context, angleUnit);
Expression * result = nullptr;
if (e->type() == Type::Power) {
result = static_cast<Power *>(e)->cloneDenominator(context, angleUnit);
} else {
assert(e->type() == Type::Multiplication);
for (int i = 0; i < e->numberOfOperands(); i++) {
// a*b^(-1)*... -> a*.../b
if (e->operand(i)->type() == Type::Power && e->operand(i)->operand(1)->type() == Type::Rational && static_cast<const Rational *>(e->operand(i)->operand(1))->isMinusOne()) {
Power * p = static_cast<Power *>(e->editableOperand(i));
result = p->editableOperand(0);
p->detachOperand((result));
}
}
}
root.detachOperand(e);
delete e;
return result;
}
Expression * Multiplication::mergeNegativePower(Context & context, AngleUnit angleUnit) {
Multiplication * m = new Multiplication();
// Special case for rational p/q: if q != 1, q should be at denominator
if (operand(0)->type() == Type::Rational && !static_cast<const Rational *>(operand(0))->denominator().isOne()) {
Rational * r = static_cast<Rational *>(editableOperand(0));
m->addOperand(new Rational(r->denominator()));
if (r->numerator().isOne()) {
removeOperand(r, true);
} else {
replaceOperand(r, new Rational(r->numerator()), true);
}
}
int i = 0;
while (i < numberOfOperands()) {
if (operand(i)->type() == Type::Power && operand(i)->operand(1)->sign() == Sign::Negative) {
Expression * e = editableOperand(i);
e->editableOperand(1)->setSign(Sign::Positive, context, angleUnit);
removeOperand(e, false);
m->addOperand(e);
e->shallowReduce(context, angleUnit);
} else {
i++;
}
}
if (m->numberOfOperands() == 0) {
delete m;
return this;
}
Power * p = new Power(m, new Rational(-1), false);
m->sortOperands(SimplificationOrder, true);
m->squashUnaryHierarchy();
addOperand(p);
sortOperands(SimplificationOrder, true);
return squashUnaryHierarchy();
}
void Multiplication::addMissingFactors(Expression * factor, Context & context, AngleUnit angleUnit) {
if (factor->type() == Type::Multiplication) {
for (int j = 0; j < factor->numberOfOperands(); j++) {
addMissingFactors(factor->editableOperand(j), context, angleUnit);
}
return;
}
/* Special case when factor is a Rational: if 'this' has already a rational
* operand, we replace it by its LCM with factor ; otherwise, we simply add
* factor as an operand. */
if (numberOfOperands() > 0 && operand(0)->type() == Type::Rational && factor->type() == Type::Rational) {
Rational * f = static_cast<Rational *>(factor);
Rational * o = static_cast<Rational *>(editableOperand(0));
assert(f->denominator().isOne());
assert(o->denominator().isOne());
Integer i = f->numerator();
Integer j = o->numerator();
return replaceOperand(o, new Rational(Arithmetic::LCM(&i, &j)));
}
if (factor->type() != Type::Rational) {
/* If factor is not a rational, we merge it with the operand of identical
* base if any. Otherwise, we add it as an new operand. */
for (int i = 0; i < numberOfOperands(); i++) {
if (TermsHaveIdenticalBase(operand(i), factor)) {
Expression * sub = new Subtraction(CreateExponent(editableOperand(i)), CreateExponent(factor), false);
Reduce((Expression **)&sub, context, angleUnit);
if (sub->sign() == Sign::Negative) { // index[0] < index[1]
if (factor->type() == Type::Power) {
factor->replaceOperand(factor->editableOperand(1), new Opposite(sub, true), true);
} else {
factor = new Power(factor, new Opposite(sub, true), false);
}
factor->editableOperand(1)->shallowReduce(context, angleUnit);
factorizeBase(editableOperand(i), factor, context, angleUnit);
editableOperand(i)->shallowReduce(context, angleUnit);
} else if (sub->sign() == Sign::Unknown) {
factorizeBase(editableOperand(i), factor, context, angleUnit);
editableOperand(i)->shallowReduce(context, angleUnit);
} else {}
delete sub;
/* Reducing the new operand i can lead to creating a new multiplication
* (ie 2^(1+2*3^(1/2)) -> 2*2^(2*3^(1/2)). We thus have to get rid of
* nested multiplication: */
mergeMultiplicationOperands();
return;
}
}
}
addOperand(factor->clone());
sortOperands(SimplificationOrder, false);
}
template MatrixComplex<float> Multiplication::computeOnComplexAndMatrix<float>(std::complex<float> const, const MatrixComplex<float>);
template MatrixComplex<double> Multiplication::computeOnComplexAndMatrix<double>(std::complex<double> const, const MatrixComplex<double>);
template std::complex<float> Multiplication::compute<float>(const std::complex<float>, const std::complex<float>);
template std::complex<double> Multiplication::compute<double>(const std::complex<double>, const std::complex<double>);
template void Multiplication::computeOnArrays<double>(double * m, double * n, double * result, int mNumberOfColumns, int mNumberOfRows, int nNumberOfColumns);
}