* multivariate polynomials and rational functions.
* These functions include polynomial quotient and remainder, GCD and LCM
* computation, square-free factorization and rational function normalization.
+ */
- *
- * GiNaC Copyright (C) 1999 Johannes Gutenberg University Mainz, Germany
+/*
+ * GiNaC Copyright (C) 1999-2000 Johannes Gutenberg University Mainz, Germany
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
*/
#include <stdexcept>
+#include <algorithm>
+#include <map>
-#include "ginac.h"
+#include "normal.h"
+#include "basic.h"
+#include "ex.h"
+#include "add.h"
+#include "constant.h"
+#include "expairseq.h"
+#include "fail.h"
+#include "indexed.h"
+#include "inifcns.h"
+#include "lst.h"
+#include "mul.h"
+#include "ncmul.h"
+#include "numeric.h"
+#include "power.h"
+#include "relational.h"
+#include "pseries.h"
+#include "symbol.h"
+#include "utils.h"
+
+#ifndef NO_NAMESPACE_GINAC
+namespace GiNaC {
+#endif // ndef NO_NAMESPACE_GINAC
// If comparing expressions (ex::compare()) is fast, you can set this to 1.
// Some routines like quo(), rem() and gcd() will then return a quick answer
x = static_cast<symbol *>(e.bp);
return true;
} else if (is_ex_exactly_of_type(e, add) || is_ex_exactly_of_type(e, mul)) {
- for (int i=0; i<e.nops(); i++)
+ for (unsigned i=0; i<e.nops(); i++)
if (get_first_symbol(e.op(i), x))
return true;
} else if (is_ex_exactly_of_type(e, power)) {
* Statistical information about symbols in polynomials
*/
-#include <algorithm>
-
/** This structure holds information about the highest and lowest degrees
* in which a symbol appears in two multivariate polynomials "a" and "b".
* A vector of these structures with information about all symbols in
if (is_ex_exactly_of_type(e, symbol)) {
add_symbol(static_cast<symbol *>(e.bp), v);
} else if (is_ex_exactly_of_type(e, add) || is_ex_exactly_of_type(e, mul)) {
- for (int i=0; i<e.nops(); i++)
+ for (unsigned i=0; i<e.nops(); i++)
collect_symbols(e.op(i), v);
} else if (is_ex_exactly_of_type(e, power)) {
collect_symbols(e.op(0), v);
{
if (e.info(info_flags::rational))
return lcm(ex_to_numeric(e).denom(), l);
- else if (is_ex_exactly_of_type(e, add) || is_ex_exactly_of_type(e, mul)) {
- numeric c = numONE();
- for (int i=0; i<e.nops(); i++) {
+ else if (is_ex_exactly_of_type(e, add)) {
+ numeric c = _num1();
+ for (unsigned i=0; i<e.nops(); i++)
c = lcmcoeff(e.op(i), c);
- }
+ return lcm(c, l);
+ } else if (is_ex_exactly_of_type(e, mul)) {
+ numeric c = _num1();
+ for (unsigned i=0; i<e.nops(); i++)
+ c *= lcmcoeff(e.op(i), _num1());
return lcm(c, l);
} else if (is_ex_exactly_of_type(e, power))
- return lcmcoeff(e.op(0), l);
+ return pow(lcmcoeff(e.op(0), l), ex_to_numeric(e.op(1)));
return l;
}
/** Compute LCM of denominators of coefficients of a polynomial.
* Given a polynomial with rational coefficients, this function computes
* the LCM of the denominators of all coefficients. This can be used
- * To bring a polynomial from Q[X] to Z[X].
+ * to bring a polynomial from Q[X] to Z[X].
*
- * @param e multivariate polynomial
+ * @param e multivariate polynomial (need not be expanded)
* @return LCM of denominators of coefficients */
static numeric lcm_of_coefficients_denominators(const ex &e)
{
- return lcmcoeff(e.expand(), numONE());
+ return lcmcoeff(e, _num1());
+}
+
+/** Bring polynomial from Q[X] to Z[X] by multiplying in the previously
+ * determined LCM of the coefficient's denominators.
+ *
+ * @param e multivariate polynomial (need not be expanded)
+ * @param lcm LCM to multiply in */
+
+static ex multiply_lcm(const ex &e, const numeric &lcm)
+{
+ if (is_ex_exactly_of_type(e, mul)) {
+ ex c = _ex1();
+ numeric lcm_accum = _num1();
+ for (unsigned i=0; i<e.nops(); i++) {
+ numeric op_lcm = lcmcoeff(e.op(i), _num1());
+ c *= multiply_lcm(e.op(i), op_lcm);
+ lcm_accum *= op_lcm;
+ }
+ c *= lcm / lcm_accum;
+ return c;
+ } else if (is_ex_exactly_of_type(e, add)) {
+ ex c = _ex0();
+ for (unsigned i=0; i<e.nops(); i++)
+ c += multiply_lcm(e.op(i), lcm);
+ return c;
+ } else if (is_ex_exactly_of_type(e, power)) {
+ return pow(multiply_lcm(e.op(0), lcm.power(ex_to_numeric(e.op(1)).inverse())), e.op(1));
+ } else
+ return e * lcm;
}
numeric ex::integer_content(void) const
{
- ASSERT(bp!=0);
+ GINAC_ASSERT(bp!=0);
return bp->integer_content();
}
numeric basic::integer_content(void) const
{
- return numONE();
+ return _num1();
}
numeric numeric::integer_content(void) const
{
epvector::const_iterator it = seq.begin();
epvector::const_iterator itend = seq.end();
- numeric c = numZERO();
+ numeric c = _num0();
while (it != itend) {
- ASSERT(!is_ex_exactly_of_type(it->rest,numeric));
- ASSERT(is_ex_exactly_of_type(it->coeff,numeric));
+ GINAC_ASSERT(!is_ex_exactly_of_type(it->rest,numeric));
+ GINAC_ASSERT(is_ex_exactly_of_type(it->coeff,numeric));
c = gcd(ex_to_numeric(it->coeff), c);
it++;
}
- ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+ GINAC_ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
c = gcd(ex_to_numeric(overall_coeff),c);
return c;
}
numeric mul::integer_content(void) const
{
-#ifdef DOASSERT
+#ifdef DO_GINAC_ASSERT
epvector::const_iterator it = seq.begin();
epvector::const_iterator itend = seq.end();
while (it != itend) {
- ASSERT(!is_ex_exactly_of_type(recombine_pair_to_ex(*it),numeric));
+ GINAC_ASSERT(!is_ex_exactly_of_type(recombine_pair_to_ex(*it),numeric));
++it;
}
-#endif // def DOASSERT
- ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+#endif // def DO_GINAC_ASSERT
+ GINAC_ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
return abs(ex_to_numeric(overall_coeff));
}
return a / b;
#if FAST_COMPARE
if (a.is_equal(b))
- return exONE();
+ return _ex1();
#endif
if (check_args && (!a.info(info_flags::rational_polynomial) || !b.info(info_flags::rational_polynomial)))
throw(std::invalid_argument("quo: arguments must be polynomials over the rationals"));
// Polynomial long division
- ex q = exZERO();
+ ex q = _ex0();
ex r = a.expand();
if (r.is_zero())
return r;
throw(std::overflow_error("rem: division by zero"));
if (is_ex_exactly_of_type(a, numeric)) {
if (is_ex_exactly_of_type(b, numeric))
- return exZERO();
+ return _ex0();
else
return b;
}
#if FAST_COMPARE
if (a.is_equal(b))
- return exZERO();
+ return _ex0();
#endif
if (check_args && (!a.info(info_flags::rational_polynomial) || !b.info(info_flags::rational_polynomial)))
throw(std::invalid_argument("rem: arguments must be polynomials over the rationals"));
throw(std::overflow_error("prem: division by zero"));
if (is_ex_exactly_of_type(a, numeric)) {
if (is_ex_exactly_of_type(b, numeric))
- return exZERO();
+ return _ex0();
else
return b;
}
if (bdeg <= rdeg) {
blcoeff = eb.coeff(x, bdeg);
if (bdeg == 0)
- eb = exZERO();
+ eb = _ex0();
else
eb -= blcoeff * power(x, bdeg);
} else
- blcoeff = exONE();
+ blcoeff = _ex1();
int delta = rdeg - bdeg + 1, i = 0;
while (rdeg >= bdeg && !r.is_zero()) {
ex rlcoeff = r.coeff(x, rdeg);
ex term = (power(x, rdeg - bdeg) * eb * rlcoeff).expand();
if (rdeg == 0)
- r = exZERO();
+ r = _ex0();
else
r -= rlcoeff * power(x, rdeg);
r = (blcoeff * r).expand() - term;
bool divide(const ex &a, const ex &b, ex &q, bool check_args)
{
- q = exZERO();
+ q = _ex0();
if (b.is_zero())
throw(std::overflow_error("divide: division by zero"));
if (is_ex_exactly_of_type(b, numeric)) {
return false;
#if FAST_COMPARE
if (a.is_equal(b)) {
- q = exONE();
+ q = _ex1();
return true;
}
#endif
* Remembering
*/
-#include <map>
-
typedef pair<ex, ex> ex2;
typedef pair<ex, bool> exbool;
* @see get_symbol_stats, heur_gcd */
static bool divide_in_z(const ex &a, const ex &b, ex &q, sym_desc_vec::const_iterator var)
{
- q = exZERO();
+ q = _ex0();
if (b.is_zero())
throw(std::overflow_error("divide_in_z: division by zero"));
- if (b.is_equal(exONE())) {
+ if (b.is_equal(_ex1())) {
q = a;
return true;
}
}
#if FAST_COMPARE
if (a.is_equal(b)) {
- q = exONE();
+ q = _ex1();
return true;
}
#endif
// Compute values at evaluation points 0..adeg
vector<numeric> alpha; alpha.reserve(adeg + 1);
exvector u; u.reserve(adeg + 1);
- numeric point = numZERO();
+ numeric point = _num0();
ex c;
for (i=0; i<=adeg; i++) {
ex bs = b.subs(*x == point);
while (bs.is_zero()) {
- point += numONE();
+ point += _num1();
bs = b.subs(*x == point);
}
if (!divide_in_z(a.subs(*x == point), bs, c, var+1))
return false;
alpha.push_back(point);
u.push_back(c);
- point += numONE();
+ point += _num1();
}
// Compute inverses
{
ex c = expand().lcoeff(x);
if (is_ex_exactly_of_type(c, numeric))
- return c < exZERO() ? exMINUSONE() : exONE();
+ return c < _ex0() ? _ex_1() : _ex1();
else {
const symbol *y;
if (get_first_symbol(c, y))
ex ex::content(const symbol &x) const
{
if (is_zero())
- return exZERO();
+ return _ex0();
if (is_ex_exactly_of_type(*this, numeric))
return info(info_flags::negative) ? -*this : *this;
ex e = expand();
if (e.is_zero())
- return exZERO();
+ return _ex0();
// First, try the integer content
ex c = e.integer_content();
int ldeg = e.ldegree(x);
if (deg == ldeg)
return e.lcoeff(x) / e.unit(x);
- c = exZERO();
+ c = _ex0();
for (int i=ldeg; i<=deg; i++)
c = gcd(e.coeff(x, i), c, NULL, NULL, false);
return c;
ex ex::primpart(const symbol &x) const
{
if (is_zero())
- return exZERO();
+ return _ex0();
if (is_ex_exactly_of_type(*this, numeric))
- return exONE();
+ return _ex1();
ex c = content(x);
if (c.is_zero())
- return exZERO();
+ return _ex0();
ex u = unit(x);
if (is_ex_exactly_of_type(c, numeric))
return *this / (c * u);
ex ex::primpart(const symbol &x, const ex &c) const
{
if (is_zero())
- return exZERO();
+ return _ex0();
if (c.is_zero())
- return exZERO();
+ return _ex0();
if (is_ex_exactly_of_type(*this, numeric))
- return exONE();
+ return _ex1();
ex u = unit(x);
if (is_ex_exactly_of_type(c, numeric))
d = d.primpart(*x, cont_d);
// First element of subresultant sequence
- ex r = exZERO(), ri = exONE(), psi = exONE();
+ ex r = _ex0(), ri = _ex1(), psi = _ex1();
int delta = cdeg - ddeg;
for (;;) {
numeric ex::max_coefficient(void) const
{
- ASSERT(bp!=0);
+ GINAC_ASSERT(bp!=0);
return bp->max_coefficient();
}
numeric basic::max_coefficient(void) const
{
- return numONE();
+ return _num1();
}
numeric numeric::max_coefficient(void) const
{
epvector::const_iterator it = seq.begin();
epvector::const_iterator itend = seq.end();
- ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+ GINAC_ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
numeric cur_max = abs(ex_to_numeric(overall_coeff));
while (it != itend) {
numeric a;
- ASSERT(!is_ex_exactly_of_type(it->rest,numeric));
+ GINAC_ASSERT(!is_ex_exactly_of_type(it->rest,numeric));
a = abs(ex_to_numeric(it->coeff));
if (a > cur_max)
cur_max = a;
numeric mul::max_coefficient(void) const
{
-#ifdef DOASSERT
+#ifdef DO_GINAC_ASSERT
epvector::const_iterator it = seq.begin();
epvector::const_iterator itend = seq.end();
while (it != itend) {
- ASSERT(!is_ex_exactly_of_type(recombine_pair_to_ex(*it),numeric));
+ GINAC_ASSERT(!is_ex_exactly_of_type(recombine_pair_to_ex(*it),numeric));
it++;
}
-#endif // def DOASSERT
- ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+#endif // def DO_GINAC_ASSERT
+ GINAC_ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
return abs(ex_to_numeric(overall_coeff));
}
ex ex::smod(const numeric &xi) const
{
- ASSERT(bp!=0);
+ GINAC_ASSERT(bp!=0);
return bp->smod(xi);
}
ex numeric::smod(const numeric &xi) const
{
+#ifndef NO_NAMESPACE_GINAC
+ return GiNaC::smod(*this, xi);
+#else // ndef NO_NAMESPACE_GINAC
return ::smod(*this, xi);
+#endif // ndef NO_NAMESPACE_GINAC
}
ex add::smod(const numeric &xi) const
epvector::const_iterator it = seq.begin();
epvector::const_iterator itend = seq.end();
while (it != itend) {
- ASSERT(!is_ex_exactly_of_type(it->rest,numeric));
+ GINAC_ASSERT(!is_ex_exactly_of_type(it->rest,numeric));
+#ifndef NO_NAMESPACE_GINAC
+ numeric coeff = GiNaC::smod(ex_to_numeric(it->coeff), xi);
+#else // ndef NO_NAMESPACE_GINAC
numeric coeff = ::smod(ex_to_numeric(it->coeff), xi);
+#endif // ndef NO_NAMESPACE_GINAC
if (!coeff.is_zero())
newseq.push_back(expair(it->rest, coeff));
it++;
}
- ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+ GINAC_ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+#ifndef NO_NAMESPACE_GINAC
+ numeric coeff = GiNaC::smod(ex_to_numeric(overall_coeff), xi);
+#else // ndef NO_NAMESPACE_GINAC
numeric coeff = ::smod(ex_to_numeric(overall_coeff), xi);
+#endif // ndef NO_NAMESPACE_GINAC
return (new add(newseq,coeff))->setflag(status_flags::dynallocated);
}
ex mul::smod(const numeric &xi) const
{
-#ifdef DOASSERT
+#ifdef DO_GINAC_ASSERT
epvector::const_iterator it = seq.begin();
epvector::const_iterator itend = seq.end();
while (it != itend) {
- ASSERT(!is_ex_exactly_of_type(recombine_pair_to_ex(*it),numeric));
+ GINAC_ASSERT(!is_ex_exactly_of_type(recombine_pair_to_ex(*it),numeric));
it++;
}
-#endif // def DOASSERT
+#endif // def DO_GINAC_ASSERT
mul * mulcopyp=new mul(*this);
- ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
- mulcopyp->overall_coeff=::smod(ex_to_numeric(overall_coeff),xi);
+ GINAC_ASSERT(is_ex_exactly_of_type(overall_coeff,numeric));
+#ifndef NO_NAMESPACE_GINAC
+ mulcopyp->overall_coeff = GiNaC::smod(ex_to_numeric(overall_coeff),xi);
+#else // ndef NO_NAMESPACE_GINAC
+ mulcopyp->overall_coeff = ::smod(ex_to_numeric(overall_coeff),xi);
+#endif // ndef NO_NAMESPACE_GINAC
mulcopyp->clearflag(status_flags::evaluated);
mulcopyp->clearflag(status_flags::hash_calculated);
return mulcopyp->setflag(status_flags::dynallocated);
}
-/** Exception thrown by heur_gcd() to signal failure */
+/** Exception thrown by heur_gcd() to signal failure. */
class gcdheu_failed {};
/** Compute GCD of multivariate polynomials using the heuristic GCD algorithm.
numeric mp = p.max_coefficient(), mq = q.max_coefficient();
numeric xi;
if (mp > mq)
- xi = mq * numTWO() + numTWO();
+ xi = mq * _num2() + _num2();
else
- xi = mp * numTWO() + numTWO();
+ xi = mp * _num2() + _num2();
// 6 tries maximum
for (int t=0; t<6; t++) {
if (!is_ex_exactly_of_type(gamma, fail)) {
// Reconstruct polynomial from GCD of mapped polynomials
- ex g = exZERO();
+ ex g = _ex0();
numeric rxi = xi.inverse();
for (int i=0; !gamma.is_zero(); i++) {
ex gi = gamma.smod(xi);
if (divide_in_z(p, g, ca ? *ca : dummy, var) && divide_in_z(q, g, cb ? *cb : dummy, var)) {
g *= gc;
ex lc = g.lcoeff(*x);
- if (is_ex_exactly_of_type(lc, numeric) && lc.compare(exZERO()) < 0)
+ if (is_ex_exactly_of_type(lc, numeric) && lc.compare(_ex0()) < 0)
return -g;
else
return g;
ex gcd(const ex &a, const ex &b, ex *ca, ex *cb, bool check_args)
{
+ // Partially factored cases (to avoid expanding large expressions)
+ if (is_ex_exactly_of_type(a, mul)) {
+ if (is_ex_exactly_of_type(b, mul) && b.nops() > a.nops())
+ goto factored_b;
+factored_a:
+ ex g = _ex1();
+ ex acc_ca = _ex1();
+ ex part_b = b;
+ for (unsigned i=0; i<a.nops(); i++) {
+ ex part_ca, part_cb;
+ g *= gcd(a.op(i), part_b, &part_ca, &part_cb, check_args);
+ acc_ca *= part_ca;
+ part_b = part_cb;
+ }
+ if (ca)
+ *ca = acc_ca;
+ if (cb)
+ *cb = part_b;
+ return g;
+ } else if (is_ex_exactly_of_type(b, mul)) {
+ if (is_ex_exactly_of_type(a, mul) && a.nops() > b.nops())
+ goto factored_a;
+factored_b:
+ ex g = _ex1();
+ ex acc_cb = _ex1();
+ ex part_a = a;
+ for (unsigned i=0; i<b.nops(); i++) {
+ ex part_ca, part_cb;
+ g *= gcd(part_a, b.op(i), &part_ca, &part_cb, check_args);
+ acc_cb *= part_cb;
+ part_a = part_ca;
+ }
+ if (ca)
+ *ca = part_a;
+ if (cb)
+ *cb = acc_cb;
+ return g;
+ }
+
// Some trivial cases
- if (a.is_zero()) {
+ ex aex = a.expand(), bex = b.expand();
+ if (aex.is_zero()) {
if (ca)
- *ca = exZERO();
+ *ca = _ex0();
if (cb)
- *cb = exONE();
+ *cb = _ex1();
return b;
}
- if (b.is_zero()) {
+ if (bex.is_zero()) {
if (ca)
- *ca = exONE();
+ *ca = _ex1();
if (cb)
- *cb = exZERO();
+ *cb = _ex0();
return a;
}
- if (a.is_equal(exONE()) || b.is_equal(exONE())) {
+ if (aex.is_equal(_ex1()) || bex.is_equal(_ex1())) {
if (ca)
*ca = a;
if (cb)
*cb = b;
- return exONE();
+ return _ex1();
}
#if FAST_COMPARE
if (a.is_equal(b)) {
if (ca)
- *ca = exONE();
+ *ca = _ex1();
if (cb)
- *cb = exONE();
+ *cb = _ex1();
return a;
}
#endif
- if (is_ex_exactly_of_type(a, numeric) && is_ex_exactly_of_type(b, numeric)) {
- numeric g = gcd(ex_to_numeric(a), ex_to_numeric(b));
+ if (is_ex_exactly_of_type(aex, numeric) && is_ex_exactly_of_type(bex, numeric)) {
+ numeric g = gcd(ex_to_numeric(aex), ex_to_numeric(bex));
if (ca)
- *ca = ex_to_numeric(a) / g;
+ *ca = ex_to_numeric(aex) / g;
if (cb)
- *cb = ex_to_numeric(b) / g;
+ *cb = ex_to_numeric(bex) / g;
return g;
}
if (check_args && !a.info(info_flags::rational_polynomial) || !b.info(info_flags::rational_polynomial)) {
- cerr << "a=" << a << endl;
- cerr << "b=" << b << endl;
throw(std::invalid_argument("gcd: arguments must be polynomials over the rationals"));
}
if (min_ldeg > 0) {
ex common = power(*x, min_ldeg);
//clog << "trivial common factor " << common << endl;
- return gcd((a / common).expand(), (b / common).expand(), ca, cb, false) * common;
+ return gcd((aex / common).expand(), (bex / common).expand(), ca, cb, false) * common;
}
// Try to eliminate variables
if (var->deg_a == 0) {
//clog << "eliminating variable " << *x << " from b" << endl;
- ex c = b.content(*x);
- ex g = gcd(a, c, ca, cb, false);
+ ex c = bex.content(*x);
+ ex g = gcd(aex, c, ca, cb, false);
if (cb)
- *cb *= b.unit(*x) * b.primpart(*x, c);
+ *cb *= bex.unit(*x) * bex.primpart(*x, c);
return g;
} else if (var->deg_b == 0) {
//clog << "eliminating variable " << *x << " from a" << endl;
- ex c = a.content(*x);
- ex g = gcd(c, b, ca, cb, false);
+ ex c = aex.content(*x);
+ ex g = gcd(c, bex, ca, cb, false);
if (ca)
- *ca *= a.unit(*x) * a.primpart(*x, c);
+ *ca *= aex.unit(*x) * aex.primpart(*x, c);
return g;
}
// Try heuristic algorithm first, fall back to PRS if that failed
ex g;
try {
- g = heur_gcd(a.expand(), b.expand(), ca, cb, var);
+ g = heur_gcd(aex, bex, ca, cb, var);
} catch (gcdheu_failed) {
g = *new ex(fail());
}
if (is_ex_exactly_of_type(g, fail)) {
-//clog << "heuristics failed\n";
- g = sr_gcd(a, b, x);
+//clog << "heuristics failed" << endl;
+ g = sr_gcd(aex, bex, x);
if (ca)
- divide(a, g, *ca, false);
+ divide(aex, g, *ca, false);
if (cb)
- divide(b, g, *cb, false);
+ divide(bex, g, *cb, false);
}
return g;
}
return b;
if (b.is_zero())
return a;
- if (a.is_equal(exONE()) || b.is_equal(exONE()))
- return exONE();
+ if (a.is_equal(_ex1()) || b.is_equal(_ex1()))
+ return _ex1();
if (is_ex_of_type(a, numeric) && is_ex_of_type(b, numeric))
return gcd(ex_to_numeric(a), ex_to_numeric(b));
if (!a.info(info_flags::rational_polynomial) || !b.info(info_flags::rational_polynomial))
ex sqrfree(const ex &a, const symbol &x)
{
int i = 1;
- ex res = exONE();
+ ex res = _ex1();
ex b = a.diff(x);
ex c = univariate_gcd(a, b, x);
ex w;
- if (c.is_equal(exONE())) {
+ if (c.is_equal(_ex1())) {
w = a;
} else {
w = quo(a, c, x);
static ex replace_with_symbol(const ex &e, lst &sym_lst, lst &repl_lst)
{
// Expression already in repl_lst? Then return the assigned symbol
- for (int i=0; i<repl_lst.nops(); i++)
+ for (unsigned i=0; i<repl_lst.nops(); i++)
if (repl_lst.op(i).is_equal(e))
return sym_lst.op(i);
if (is_real())
if (is_rational())
return *this;
- else
- return replace_with_symbol(*this, sym_lst, repl_lst);
+ else
+ return replace_with_symbol(*this, sym_lst, repl_lst);
else { // complex
numeric re = real(), im = imag();
- ex re_ex = re.is_rational() ? re : replace_with_symbol(re, sym_lst, repl_lst);
- ex im_ex = im.is_rational() ? im : replace_with_symbol(im, sym_lst, repl_lst);
- return re_ex + im_ex * replace_with_symbol(I, sym_lst, repl_lst);
- }
+ ex re_ex = re.is_rational() ? re : replace_with_symbol(re, sym_lst, repl_lst);
+ ex im_ex = im.is_rational() ? im : replace_with_symbol(im, sym_lst, repl_lst);
+ return re_ex + im_ex * replace_with_symbol(I, sym_lst, repl_lst);
+ }
}
-/*
- * Helper function for fraction cancellation (returns cancelled fraction n/d)
- */
-
+/** Fraction cancellation.
+ * @param n numerator
+ * @param d denominator
+ * @return cancelled fraction n/d */
static ex frac_cancel(const ex &n, const ex &d)
{
ex num = n;
ex den = d;
- ex pre_factor = exONE();
+ numeric pre_factor = _num1();
// Handle special cases where numerator or denominator is 0
if (num.is_zero())
- return exZERO();
+ return _ex0();
if (den.expand().is_zero())
throw(std::overflow_error("frac_cancel: division by zero in frac_cancel"));
// More special cases
if (is_ex_exactly_of_type(den, numeric))
return num / den;
- if (num.is_zero())
- return exZERO();
// Bring numerator and denominator to Z[X] by multiplying with
// LCM of all coefficients' denominators
- ex num_lcm = lcm_of_coefficients_denominators(num);
- ex den_lcm = lcm_of_coefficients_denominators(den);
- num *= num_lcm;
- den *= den_lcm;
+ numeric num_lcm = lcm_of_coefficients_denominators(num);
+ numeric den_lcm = lcm_of_coefficients_denominators(den);
+ num = multiply_lcm(num, num_lcm);
+ den = multiply_lcm(den, den_lcm);
pre_factor = den_lcm / num_lcm;
// Cancel GCD from numerator and denominator
ex cnum, cden;
- if (gcd(num, den, &cnum, &cden, false) != exONE()) {
+ if (gcd(num, den, &cnum, &cden, false) != _ex1()) {
num = cnum;
den = cden;
}
// as defined by get_first_symbol() is made positive)
const symbol *x;
if (get_first_symbol(den, x)) {
- if (den.unit(*x).compare(exZERO()) < 0) {
- num *= exMINUSONE();
- den *= exMINUSONE();
+ if (den.unit(*x).compare(_ex0()) < 0) {
+ num *= _ex_1();
+ den *= _ex_1();
}
}
return pre_factor * num / den;
o.push_back(overall_coeff.bp->normal(sym_lst, repl_lst, level-1));
// Determine common denominator
- ex den = exONE();
+ ex den = _ex1();
exvector::const_iterator ait = o.begin(), aitend = o.end();
while (ait != aitend) {
den = lcm((*ait).denom(false), den, false);
}
// Add fractions
- if (den.is_equal(exONE()))
+ if (den.is_equal(_ex1()))
return (new add(o))->setflag(status_flags::dynallocated);
else {
exvector num_seq;
}
-/** Implementation of ex::normal() for series. It normalizes each coefficient and
+/** Implementation of ex::normal() for pseries. It normalizes each coefficient and
* replaces the series by a temporary symbol.
* @see ex::normal */
-ex series::normal(lst &sym_lst, lst &repl_lst, int level) const
+ex pseries::normal(lst &sym_lst, lst &repl_lst, int level) const
{
epvector new_seq;
new_seq.reserve(seq.size());
it++;
}
- ex n = series(var, point, new_seq);
+ ex n = pseries(var, point, new_seq);
return replace_with_symbol(n, sym_lst, repl_lst);
}
else
return e;
}
+
+#ifndef NO_NAMESPACE_GINAC
+} // namespace GiNaC
+#endif // ndef NO_NAMESPACE_GINAC