source: git/factory/cf_algorithm.cc @ 5df7d0

/* emacs edit mode for this file is -*- C++ -*- */
/* $Id$ */

//{{{ docu
//
// cf_algorithm.cc - simple mathematical algorithms.
//
// Hierarchy: mathematical algorithms on canonical forms
//
// Developers note:
// ----------------
// A "mathematical" algorithm is an algorithm which calculates
// some mathematical function in contrast to a "structural"
// algorithm which gives structural information on polynomials.
//
// Compare these functions to the functions in `cf_ops.cc', which
// are structural algorithms.
//
//}}}

#include <config.h>

#include "assert.h"

#include "cf_factory.h"
#include "cf_defs.h"
#include "canonicalform.h"
#include "cf_algorithm.h"
#include "variable.h"
#include "cf_iter.h"
#include "templates/ftmpl_functions.h"

void out_cf(const char *s1,const CanonicalForm &f,const char *s2);

//{{{ CanonicalForm psr ( const CanonicalForm & f, const CanonicalForm & g, const Variable & x )
//{{{ docu
//
// psr() - return pseudo remainder of `f' and `g' with respect
//   to `x'.
//
// `g' must not equal zero.
//
// For f and g in R[x], R an arbitrary ring, g != 0, there is a
// representation
//
//   LC(g)^s*f = g*q + r
//
// with r = 0 or deg(r) < deg(g) and s = 0 if f = 0 or
// s = max( 0, deg(f)-deg(g)+1 ) otherwise.
// r = psr(f, g) and q = psq(f, g) are called "pseudo remainder"
// and "pseudo quotient", resp.  They are uniquely determined if
// LC(g) is not a zero divisor in R.
//
// See H.-J. Reiffen/G. Scheja/U. Vetter - "Algebra", 2nd ed.,
// par. 15, for a reference.
//
// Type info:
// ----------
// f, g: Current
// x: Polynomial
//
// Polynomials over prime power domains are admissible if
// lc(LC(`g',`x')) is not a zero divisor.  This is a slightly
// stronger precondition than mathematically necessary since
// pseudo remainder and quotient are well-defined if LC(`g',`x')
// is not a zero divisor.
//
// For example, psr(y^2, (13*x+1)*y) is well-defined in
// (Z/13^2[x])[y] since (13*x+1) is not a zero divisor.  But
// calculating it with Factory would fail since 13 is a zero
// divisor in Z/13^2.
//
// Due to this inconsistency with mathematical notion, we decided
// not to declare type `CurrentPP' for `f' and `g'.
//
// Developers note:
// ----------------
// This is not an optimal implementation.  Better would have been
// an implementation in `InternalPoly' avoiding the
// exponentiation of the leading coefficient of `g'.  In contrast
// to `psq()' and `psqr()' it definitely seems worth to implement
// the pseudo remainder on the internal level.  Should be done
// soon.
//
//}}}
CanonicalForm
#if 0
psr ( const CanonicalForm & f, const CanonicalForm & g, const Variable & x )
{

    ASSERT( x.level() > 0, "type error: polynomial variable expected" );
    ASSERT( ! g.isZero(), "math error: division by zero" );

    // swap variables such that x's level is larger or equal
    // than both f's and g's levels.
    Variable X = tmax( tmax( f.mvar(), g.mvar() ), x );
    CanonicalForm F = swapvar( f, x, X );
    CanonicalForm G = swapvar( g, x, X );

    // now, we have to calculate the pseudo remainder of F and G
    // w.r.t. X
    int fDegree = degree( F, X );
    int gDegree = degree( G, X );
    if ( (fDegree < 0) || (fDegree < gDegree) )
        return f;
    else
    {
        CanonicalForm xresult = (power( LC( G, X ), fDegree-gDegree+1 ) * F) ;
        CanonicalForm result = xresult -(xresult/G)*G;
        return swapvar( result, x, X );
    }
}
#else
psr ( const CanonicalForm &rr, const CanonicalForm &vv, const Variable & x )
{
  CanonicalForm r=rr, v=vv, l, test, lu, lv, t, retvalue;
  int dr, dv, d,n=0;


  dr = degree( r, x );
  if (dr>0)
  {
    dv = degree( v, x );
    if (dv <= dr) {l=LC(v,x); v = v -l*power(x,dv);}
    else { l = 1; }
    d= dr-dv+1;
    //out_cf("psr(",rr," ");
    //out_cf("",vv," ");
    //printf(" var=%d\n",x.level());
    while ( ( dv <= dr  ) && ( !r.isZero()) )
    {
      test = power(x,dr-dv)*v*LC(r,x);
      if ( dr == 0 ) { r= CanonicalForm(0); }
      else { r= r - LC(r,x)*power(x,dr); }
      r= l*r -test;
      dr= degree(r,x);
      n+=1;
    }
    r= power(l, d-n)*r;
  }
  return r;
}
#endif
//}}}

//{{{ CanonicalForm psq ( const CanonicalForm & f, const CanonicalForm & g, const Variable & x )
//{{{ docu
//
// psq() - return pseudo quotient of `f' and `g' with respect
//   to `x'.
//
// `g' must not equal zero.
//
// See `psr()' for more detailed information.
//
// Type info:
// ----------
// f, g: Current
// x: Polynomial
//
// Developers note:
// ----------------
// This is not an optimal implementation.  Better would have been
// an implementation in `InternalPoly' avoiding the
// exponentiation of the leading coefficient of `g'.  It seemed
// not worth to do so.
//
//}}}
CanonicalForm
psq ( const CanonicalForm & f, const CanonicalForm & g, const Variable & x )
{
    ASSERT( x.level() > 0, "type error: polynomial variable expected" );
    ASSERT( ! g.isZero(), "math error: division by zero" );

    // swap variables such that x's level is larger or equal
    // than both f's and g's levels.
    Variable X = tmax( tmax( f.mvar(), g.mvar() ), x );
    CanonicalForm F = swapvar( f, x, X );
    CanonicalForm G = swapvar( g, x, X );

    // now, we have to calculate the pseudo remainder of F and G
    // w.r.t. X
    int fDegree = degree( F, X );
    int gDegree = degree( G, X );
    if ( fDegree < 0 || fDegree < gDegree )
        return 0;
    else {
        CanonicalForm result = (power( LC( G, X ), fDegree-gDegree+1 ) * F) / G;
        return swapvar( result, x, X );
    }
}
//}}}

//{{{ void psqr ( const CanonicalForm & f, const CanonicalForm & g, CanonicalForm & q, CanonicalForm & r, const Variable & x )
//{{{ docu
//
// psqr() - calculate pseudo quotient and remainder of `f' and
//   `g' with respect to `x'.
//
// Returns the pseudo quotient of `f' and `g' in `q', the pseudo
// remainder in `r'.  `g' must not equal zero.
//
// See `psr()' for more detailed information.
//
// Type info:
// ----------
// f, g: Current
// q, r: Anything
// x: Polynomial
//
// Developers note:
// ----------------
// This is not an optimal implementation.  Better would have been
// an implementation in `InternalPoly' avoiding the
// exponentiation of the leading coefficient of `g'.  It seemed
// not worth to do so.
//
//}}}
void
psqr ( const CanonicalForm & f, const CanonicalForm & g, CanonicalForm & q, CanonicalForm & r, const Variable& x )
{
    ASSERT( x.level() > 0, "type error: polynomial variable expected" );
    ASSERT( ! g.isZero(), "math error: division by zero" );

    // swap variables such that x's level is larger or equal
    // than both f's and g's levels.
    Variable X = tmax( tmax( f.mvar(), g.mvar() ), x );
    CanonicalForm F = swapvar( f, x, X );
    CanonicalForm G = swapvar( g, x, X );

    // now, we have to calculate the pseudo remainder of F and G
    // w.r.t. X
    int fDegree = degree( F, X );
    int gDegree = degree( G, X );
    if ( fDegree < 0 || fDegree < gDegree ) {
        q = 0; r = f;
    } else {
        divrem( power( LC( G, X ), fDegree-gDegree+1 ) * F, G, q, r );
        q = swapvar( q, x, X );
        r = swapvar( r, x, X );
    }
}
//}}}

//{{{ static CanonicalForm internalBCommonDen ( const CanonicalForm & f )
//{{{ docu
//
// internalBCommonDen() - recursively calculate multivariate
//   common denominator of coefficients of `f'.
//
// Used by: bCommonDen()
//
// Type info:
// ----------
// f: Poly( Q )
// Switches: isOff( SW_RATIONAL )
//
//}}}
static CanonicalForm
internalBCommonDen ( const CanonicalForm & f )
{
    if ( f.inBaseDomain() )
        return f.den();
    else {
        CanonicalForm result = 1;
        for ( CFIterator i = f; i.hasTerms(); i++ )
            result = blcm( result, internalBCommonDen( i.coeff() ) );
        return result;
    }
}
//}}}

//{{{ CanonicalForm bCommonDen ( const CanonicalForm & f )
//{{{ docu
//
// bCommonDen() - calculate multivariate common denominator of
//   coefficients of `f'.
//
// The common denominator is calculated with respect to all
// coefficients of `f' which are in a base domain.  In other
// words, common_den( `f' ) * `f' is guaranteed to have integer
// coefficients only.  The common denominator of zero is one.
//
// Returns something non-trivial iff the current domain is Q.
//
// Type info:
// ----------
// f: CurrentPP
//
//}}}
CanonicalForm
bCommonDen ( const CanonicalForm & f )
{
    if ( getCharacteristic() == 0 && isOn( SW_RATIONAL ) ) {
        // otherwise `bgcd()' returns one
        Off( SW_RATIONAL );
        CanonicalForm result = internalBCommonDen( f );
        On( SW_RATIONAL );
        return result;
    } else
        return CanonicalForm( 1 );
}
//}}}

//{{{ bool fdivides ( const CanonicalForm & f, const CanonicalForm & g )
//{{{ docu
//
// fdivides() - check whether `f' divides `g'.
//
// Returns true iff `f' divides `g'.  Uses some extra heuristic
// to avoid polynomial division.  Without the heuristic, the test
// essentialy looks like `divremt(g, f, q, r) && r.isZero()'.
//
// Type info:
// ----------
// f, g: Current
//
// Elements from prime power domains (or polynomials over such
// domains) are admissible if `f' (or lc(`f'), resp.) is not a
// zero divisor.  This is a slightly stronger precondition than
// mathematically necessary since divisibility is a well-defined
// notion in arbitrary rings.  Hence, we decided not to declare
// the weaker type `CurrentPP'.
//
// Developers note:
// ----------------
// One may consider the the test `fdivides( f.LC(), g.LC() )' in
// the main `if'-test superfluous since `divremt()' in the
// `if'-body repeats the test.  However, `divremt()' does not use
// any heuristic to do so.
//
// It seems not reasonable to call `fdivides()' from `divremt()'
// to check divisibility of leading coefficients.  `fdivides()' is
// on a relatively high level compared to `divremt()'.
//
//}}}
bool
fdivides ( const CanonicalForm & f, const CanonicalForm & g )
{
    // trivial cases
    if ( g.isZero() )
        return true;
    else if ( f.isZero() )
        return false;

    if ( (f.inCoeffDomain() || g.inCoeffDomain())
         && ((getCharacteristic() == 0 && isOn( SW_RATIONAL ))
             || (getCharacteristic() > 0 && CFFactory::gettype() != PrimePowerDomain)) )
    {
        // if we are in a field all elements not equal to zero are units
        if ( f.inCoeffDomain() )
            return true;
        else
            // g.inCoeffDomain()
            return false;
    }

    // we may assume now that both levels either equal LEVELBASE
    // or are greater zero
    int fLevel = f.level();
    int gLevel = g.level();
    if ( (gLevel > 0) && (fLevel == gLevel) )
        // f and g are polynomials in the same main variable
        if ( degree( f ) <= degree( g )
             && fdivides( f.tailcoeff(), g.tailcoeff() )
             && fdivides( f.LC(), g.LC() ) )
        {
            CanonicalForm q, r;
            return divremt( g, f, q, r ) && r.isZero();
        }
        else
            return false;
    else if ( gLevel < fLevel )
        // g is a coefficient w.r.t. f
        return false;
    else
    {
        // either f is a coefficient w.r.t. polynomial g or both
        // f and g are from a base domain (should be Z or Z/p^n,
        // then)
        CanonicalForm q, r;
        return divremt( g, f, q, r ) && r.isZero();
    }
}
//}}}

//{{{ CanonicalForm maxNorm ( const CanonicalForm & f )
//{{{ docu
//
// maxNorm() - return maximum norm of `f'.
//
// That is, the base coefficient of `f' with the largest absolute
// value.
//
// Valid for arbitrary polynomials over arbitrary domains, but
// most useful for multivariate polynomials over Z.
//
// Type info:
// ----------
// f: CurrentPP
//
//}}}
CanonicalForm
maxNorm ( const CanonicalForm & f )
{
    if ( f.inBaseDomain() )
        return abs( f );
    else {
        CanonicalForm result = 0;
        for ( CFIterator i = f; i.hasTerms(); i++ ) {
            CanonicalForm coeffMaxNorm = maxNorm( i.coeff() );
            if ( coeffMaxNorm > result )
                result = coeffMaxNorm;
        }
        return result;
    }
}
//}}}

//{{{ CanonicalForm euclideanNorm ( const CanonicalForm & f )
//{{{ docu
//
// euclideanNorm() - return Euclidean norm of `f'.
//
// Returns the largest integer smaller or equal norm(`f') =
// sqrt(sum( `f'[i]^2 )).
//
// Type info:
// ----------
// f: UVPoly( Z )
//
//}}}
CanonicalForm
euclideanNorm ( const CanonicalForm & f )
{
    ASSERT( (f.inBaseDomain() || f.isUnivariate()) && f.LC().inZ(),
            "type error: univariate poly over Z expected" );

    CanonicalForm result = 0;
    for ( CFIterator i = f; i.hasTerms(); i++ ) {
        CanonicalForm coeff = i.coeff();
        result += coeff*coeff;
    }
    return sqrt( result );
}
//}}}