intervalarith.c
Go to the documentation of this file.
23 /*---+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0----+----1----+----2*/
210 #if defined(__GNUC__) && (defined(__i386__) || defined(__x86_64__)) /* gcc or icc compiler on x86 32bit or 64bit */
213 * Do this in a way that the compiler does not "optimize" it away, which usually does not considers rounding modes.
218 /* we explicitely use double here, since I'm not sure the assembler code would work as it for other float's */
233 * Do this in a way that the compiler does not "optimize" it away, which usually does not considers rounding modes.
237 /* we explicitely use double here, since I'm not sure the assembler code would work as it for other float's */
513 /* [a,...] + [-inf,...] = [-inf,...] for all a, in particular, [+inf,...] + [-inf,...] = [-inf,...] */
540 /* [...,b] + [...,+inf] = [...,+inf] for all b, in particular, [...,-inf] + [...,+inf] = [...,+inf] */
699 assert(resultant->inf == -infinity); /* should be set above, since operand1.inf <= operand1.sup <= -infinity */ /*lint !e777*/
869 /** multiplies operand1 with scalar operand2 and stores infimum of result in infimum of resultant */
925 /** multiplies operand1 with scalar operand2 and stores supremum of result in supremum of resultant */
1204 /** computes scalar product of a vector of intervals and a vector of scalars and stores infimum of result in infimum of
1232 /** computes the scalar product of a vector of intervals and a vector of scalars and stores supremum of result in
1260 /** computes the scalar product of a vector of intervals and a vector of scalars and stores result in resultant */
1387 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1405 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1413 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1584 /* use a binary exponentiation algorithm... see comments in SCIPintervalPowerScalarIntegerInf */
1648 SCIPintervalReciprocal(SCIP_REAL_MAX, resultant, *resultant); /* value for infinity does not matter, since there should be no 0.0 in the interval, so just use something large enough */
1699 * need to have operand1 >= 0 or operand2 integer and need to have operand2 >= 0 if operand1 == 0
1734 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1822 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1832 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1853 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1862 assert(SCIPintervalGetRoundingMode() == SCIP_ROUND_NEAREST); /* usually, no-one should have changed rounding mode */
1937 assert(resultant->inf <= resultant->sup || resultant->inf >= infinity || resultant->sup <= -infinity);
1941 assert(op2isint); /* otherwise we had set operand1.inf == 0.0, which was handled in first case */
1949 resultant->sup = SCIPintervalPowerScalarIntegerSup(MAX(-operand1.inf, operand1.sup), (int)operand2);
1958 resultant->inf = SCIPintervalPowerScalarIntegerInf(MAX(-operand1.inf, operand1.sup), (int)operand2);
1991 * computes a subinterval x of basedomain such that y in x^p and such that for all z in basedomain less x, z^p not in y
2044 if( basedomain.inf <= -resultant->inf && EPSISINT(exponent, 0.0) && (int)exponent % 2 == 0 ) /*lint !e835 */
2057 /* invert negative part of image, if any and if base can take negative value and if exponent is such that negative values are possible */
2058 if( image.inf < 0.0 && basedomain.inf < 0.0 && EPSISINT(exponent, 0.0) && ((int)exponent % 2 != 0) ) /*lint !e835 */
2072 * @attention we assume correctly rounded sqrt(double) and pow(double) functions when rounding is to nearest
2378 /* make sure we do not exceed value for infinity, so interval is not declared as empty if inf and sup are both > infinity */
2604 * so extend the computed interval slightly to increase the chance that it will contain the complete sin(operand)
2690 * so extend the computed interval slightly to increase the chance that it will contain the complete cos(operand)
2727 /** computes exact upper bound on \f$ a x^2 + b x \f$ for x in [xlb, xub], b an interval, and a scalar
2729 * Uses Algorithm 2.2 from Domes and Neumaier: Constraint propagation on quadratic constraints (2008) */
2856 /** computes interval with positive solutions of a quadratic equation with interval coefficients
2858 * Given intervals a, b, and c, this function computes an interval that contains all positive solutions of \f$ a x^2 + b x \in c\f$ within xbnds.
2879 SCIPintervalSolveUnivariateQuadExpressionPositiveAllScalar(infinity, resultant, -sqrcoeff.inf, -lincoeff.inf, -rhs.sup, xbnds);
2880 SCIPdebugMessage("solve %g*x^2 + %g*x >= %g gives [%.20f, %.20f]\n", -sqrcoeff.inf, -lincoeff.inf, -rhs.sup, resultant->inf, resultant->sup);
2887 SCIPintervalSolveUnivariateQuadExpressionPositiveAllScalar(infinity, &res2, sqrcoeff.sup, lincoeff.sup, rhs.inf, xbnds);
2888 SCIPdebugMessage("solve %g*x^2 + %g*x >= %g gives [%.20f, %.20f]\n", sqrcoeff.sup, lincoeff.sup, rhs.inf, res2.inf, res2.sup);
2889 SCIPdebugMessage("intersection of [%.20f, %.20f] and [%.20f, %.20f]", resultant->inf, resultant->sup, res2.inf, res2.sup);
2902 /** computes interval with negative solutions of a quadratic equation with interval coefficients
2904 * Given intervals a, b, and c, this function computes an interval that contains all negative solutions of \f$ a x^2 + b x \in c\f$ within xbnds.
2929 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, resultant, sqrcoeff, lincoeff, rhs, xbnds);
2939 * Given scalar a, b, and c, this function computes an interval that contains all positive solutions of \f$ a x^2 + b x \geq c\f$ within xbnds.
2940 * Implements Algorithm 3.2 from Domes and Neumaier: Constraint propagation on quadratic constraints (2008).
2970 * The same should have been computed below, but without the sqrcoeff, terms simplify (thus, also less rounding).
3144 * Given intervals a, b and c, this function computes an interval that contains all solutions of \f$ a x^2 + b x \in c\f$ within xbnds
3165 * the code below would also work, but uses many more case distinctions to get to a result that should be the same (though epsilon differences can sometimes be observed)
3171 SCIPdebugMessage("solving [%g,%g]*x = [%g,%g] for x in [%g,%g] gives [%g,%g]\n", lincoeff.inf, lincoeff.sup, rhs.inf, rhs.sup, xbnds.inf, xbnds.sup, resultant->inf, resultant->sup);
3175 SCIPdebugMessage("solving [%g,%g]*x^2 + [%g,%g]*x = [%g,%g] for x in [%g,%g]\n", sqrcoeff.inf, sqrcoeff.sup, lincoeff.inf, lincoeff.sup, rhs.inf, rhs.sup, xbnds.inf, xbnds.sup);
3180 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, &xpos, sqrcoeff, lincoeff, rhs, xbnds);
3181 SCIPdebugMessage(" solutions of [%g,%g]*x^2 + [%g,%g]*x in [%g,%g] for x in [%g,%g] are [%.20g,%.20g]\n",
3182 sqrcoeff.inf, sqrcoeff.sup, lincoeff.inf, lincoeff.sup, rhs.inf, rhs.sup, MAX(xbnds.inf, 0.0), xbnds.sup, xpos.inf, xpos.sup);
3192 SCIPintervalSolveUnivariateQuadExpressionNegative(infinity, &xneg, sqrcoeff, lincoeff, rhs, xbnds);
3193 SCIPdebugMessage(" solutions of [%g,%g]*x^2 + [%g,%g]*x in [%g,%g] for x in [%g,%g] are [%g,%g]\n",
3194 sqrcoeff.inf, sqrcoeff.sup, lincoeff.inf, lincoeff.sup, rhs.inf, rhs.sup, xbnds.inf, MIN(xbnds.sup, 0.0), xneg.inf, xneg.sup);
3202 SCIPdebugMessage(" unify gives [%g,%g]\n", SCIPintervalGetInf(*resultant), SCIPintervalGetSup(*resultant));
3206 * given scalars ax, ay, axy, bx, and by and intervals for x and y, computes interval for \f$ ax x^2 + ay y^2 + axy x y + bx x + by y \f$
3221 /* we use double double precision and finally widen the computed range by 1e-8% to compensate for not computing rounding-safe here */
3269 /* The whole line (x, -bx/axy - (axy/2ay) x) defines an extreme point with value -ay bx^2 / axy^2
3270 * If x is unbounded, then there is an (x,y) with y in ybnds where the extreme value is assumed.
3271 * If x is bounded on at least one side, then we can rely that the checks below for x at one of its bounds will check this extreme point.
3321 SCIPintervalAddScalar(infinity, &tmp, tmp, (SCIP_Real)(ax * xbnds.inf * xbnds.inf + bx * xbnds.inf));
3364 SCIPintervalAddScalar(infinity, &tmp, tmp, (SCIP_Real)(ax * xbnds.sup * xbnds.sup + bx * xbnds.sup));
3450 SCIPintervalAddScalar(infinity, &tmp, tmp, (SCIP_Real)(ay * ybnds.sup * ybnds.sup + by * ybnds.sup));
3459 SCIPdebugMessage("range for %gx^2 + %gy^2 + %gxy + %gx + %gy = [%g, %g] for x = [%g, %g], y=[%g, %g]\n",
3465 * computes \f$ \{ x \in \mathbf{x} : \exists y \in \mathbf{y} : a_x x^2 + a_y y^2 + a_{xy} x y + b_x x + b_y y \in \mathbf{\mbox{rhs}} \} \f$
3481 /* we use double double precision and finally widen the computed range by 1e-8% to compensate for not computing rounding-safe here */
3505 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, &pos, sqrcoef, lincoef, rhs, xbnds);
3516 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, &neg, sqrcoef, lincoef, rhs, xbndsneg);
3531 * fall back to univariate case by solving a_x x^2 + b_x x + a_y y^2 + (a_xy xbnds + b_y) y in rhs
3567 SCIPintervalSolveBivariateQuadExpressionAllScalar(infinity, resultant, -ax, -ay, -axy, -bx, -by, rhs, xbnds, ybnds);
3607 ub = (SCIP_Real)(SCIPintervalQuadUpperBound(infinity, (SCIP_Real)rcoef_yy, ycoef, ybnds) + rhs.sup + rcoef_const);
3616 /* it looks like there will be no solution (rhs < 0), but we are very close and above operations did not take care of careful rounding
3617 * thus, we relax rhs a be feasible a bit (-ub would be sufficient, but that would put us exactly onto the boundary)
3672 /* here axy * axy < 4 * ax * ay, so need to check for zeros of r(rhs,y), which is done below */
3746 /* here axy * axy < 4 * ax * ay, so need to check for zeros of r(rhs,y), which will happen below */
3803 sqrtterm = axy * axy * ay * (ay * bx * bx - axy * bx * by + ax * by * by - axy * axy * rhs.sup + 4.0 * ax * ay * rhs.sup);
3857 sqrtterm = axy * axy * ay * (ay * bx * bx - axy * bx * by + ax * by * by - axy * axy * rhs.inf + 4.0 * ax * ay * rhs.inf);
3982 SCIPintervalSetBounds(&rhs2, (SCIP_Real)(-rhs.sup - rcoef_const), (SCIP_Real)(-rhs.inf - rcoef_const));
3991 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, &ypos, rcoef_yy_int, rcoef_y_int, rhs2, ybnds);
4034 SCIPintervalSolveUnivariateQuadExpressionNegative(infinity, &yneg, rcoef_yy_int, rcoef_y_int, rhs2, ybnds);
4070 if( rhs.inf > -infinity && xbnds.inf > -infinity && EPSGT(xbnds.inf, maxvalleft / sqrtax, 1e-9) )
4072 /* if sqrt(ax)*x > -sqrt(r(rhs,y))-b(y), then tighten lower bound of sqrt(ax)*x to lower bound of sqrt(r(rhs,y))-b(y)
4073 * this is only possible if rhs.inf > -infinity, otherwise the value for maxvalleft is not valid (but tightening wouldn't be possible for sure anyway) */
4074 assert(EPSGE(minvalright, minvalleft, 1e-9)); /* right interval should not be above lower bound of left interval */
4091 if( rhs.inf > -infinity && xbnds.sup < infinity && EPSLT(xbnds.sup, minvalright / sqrtax, 1e-9) )
4093 /* if sqrt(ax)*x < sqrt(r(rhs,y))-b(y), then tighten upper bound of sqrt(ax)*x to upper bound of -sqrt(r(rhs,y))-b(y)
4094 * this is only possible if rhs.inf > -infinity, otherwise the value for minvalright is not valid (but tightening wouldn't be possible for sure anyway) */
4095 assert(EPSLE(maxvalleft, maxvalright, 1e-9)); /* left interval should not be above upper bound of right interval */
4171 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, resultant, a_, lincoef, myrhs, xbnds);
4184 SCIPintervalSolveUnivariateQuadExpressionPositive(infinity, resultant, a_, lincoef, myrhs, xbndsneg);
void SCIPintervalSignPowerScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:2074
void SCIPintervalDivScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:1062
void SCIPintervalMulSup(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:783
void SCIPintervalSubScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:712
void SCIPintervalMax(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:2487
SCIP_Bool SCIPintervalIsEmpty(SCIP_Real infinity, SCIP_INTERVAL operand)
Definition: intervalarith.c:384
void SCIPintervalSign(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2701
Definition: intervalarith.h:37
void SCIPintervalAddSup(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:530
void SCIPintervalSolveUnivariateQuadExpressionNegative(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL sqrcoeff, SCIP_INTERVAL lincoeff, SCIP_INTERVAL rhs, SCIP_INTERVAL xbnds)
Definition: intervalarith.c:2906
void SCIPintervalSolveUnivariateQuadExpressionPositiveAllScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_Real sqrcoeff, SCIP_Real lincoeff, SCIP_Real rhs, SCIP_INTERVAL xbnds)
Definition: intervalarith.c:2942
void SCIPintervalSetRoundingMode(SCIP_ROUNDMODE roundmode)
Definition: intervalarith.c:191
void SCIPintervalMul(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:843
SCIP_Real SCIPintervalPowerScalarIntegerInf(SCIP_Real operand1, int operand2)
Definition: intervalarith.c:1455
void SCIPintervalMin(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:2471
void SCIPintervalSetBounds(SCIP_INTERVAL *resultant, SCIP_Real inf, SCIP_Real sup)
Definition: intervalarith.c:359
void SCIPintervalPowerScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:1745
SCIP_Bool SCIPintervalIsNegativeInfinity(SCIP_Real infinity, SCIP_INTERVAL operand)
Definition: intervalarith.c:426
void SCIPintervalDiv(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:1008
void SCIPintervalAddVectors(SCIP_Real infinity, SCIP_INTERVAL *resultant, int length, SCIP_INTERVAL *operand1, SCIP_INTERVAL *operand2)
Definition: intervalarith.c:634
SCIP_Bool SCIPintervalIsPositiveInfinity(SCIP_Real infinity, SCIP_INTERVAL operand)
Definition: intervalarith.c:417
void SCIPintervalSin(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2531
void SCIPintervalPowerScalarScalar(SCIP_INTERVAL *resultant, SCIP_Real operand1, SCIP_Real operand2)
Definition: intervalarith.c:1702
SCIP_Bool SCIPintervalIsEntire(SCIP_Real infinity, SCIP_INTERVAL operand)
Definition: intervalarith.c:408
void SCIPintervalScalprod(SCIP_Real infinity, SCIP_INTERVAL *resultant, int length, SCIP_INTERVAL *operand1, SCIP_INTERVAL *operand2)
Definition: intervalarith.c:1165
interval arithmetics for provable bounds
void SCIPintervalSetEmpty(SCIP_INTERVAL *resultant)
Definition: intervalarith.c:373
SCIP_Real SCIPintervalGetInf(SCIP_INTERVAL interval)
Definition: intervalarith.c:331
void SCIPintervalLog(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2403
void SCIPintervalScalprodScalarsInf(SCIP_Real infinity, SCIP_INTERVAL *resultant, int length, SCIP_INTERVAL *operand1, SCIP_Real *operand2)
Definition: intervalarith.c:1207
internal miscellaneous methods
void SCIPintervalSet(SCIP_INTERVAL *resultant, SCIP_Real value)
Definition: intervalarith.c:347
void SCIPintervalPowerScalarInteger(SCIP_INTERVAL *resultant, SCIP_Real operand1, int operand2)
Definition: intervalarith.c:1611
void SCIPintervalCos(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2617
void SCIPintervalSolveUnivariateQuadExpression(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL sqrcoeff, SCIP_INTERVAL lincoeff, SCIP_INTERVAL rhs, SCIP_INTERVAL xbnds)
Definition: intervalarith.c:3146
void SCIPintervalSolveBivariateQuadExpressionAllScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_Real ax, SCIP_Real ay, SCIP_Real axy, SCIP_Real bx, SCIP_Real by, SCIP_INTERVAL rhs, SCIP_INTERVAL xbnds, SCIP_INTERVAL ybnds)
Definition: intervalarith.c:3468
void SCIPintervalSquareRoot(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:1361
void SCIPintervalQuadBivar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_Real ax, SCIP_Real ay, SCIP_Real axy, SCIP_Real bx, SCIP_Real by, SCIP_INTERVAL xbnds, SCIP_INTERVAL ybnds)
Definition: intervalarith.c:3209
void SCIPintervalSquare(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:1289
void SCIPintervalScalprodScalars(SCIP_Real infinity, SCIP_INTERVAL *resultant, int length, SCIP_INTERVAL *operand1, SCIP_Real *operand2)
Definition: intervalarith.c:1261
SCIP_Bool SCIPintervalHasRoundingControl(void)
Definition: intervalarith.c:183
void SCIPintervalSetRoundingModeTowardsZero(void)
Definition: intervalarith.c:294
void SCIPintervalAdd(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:557
SCIP_Real SCIPintervalGetSup(SCIP_INTERVAL interval)
Definition: intervalarith.c:339
SCIP_Bool SCIPintervalAreDisjoint(SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:454
void SCIPintervalMulScalarSup(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:926
void SCIPintervalAbs(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2503
void SCIPintervalMulScalarInf(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:870
void SCIPintervalSetEntire(SCIP_Real infinity, SCIP_INTERVAL *resultant)
Definition: intervalarith.c:396
SCIP_Real SCIPintervalQuadUpperBound(SCIP_Real infinity, SCIP_Real a, SCIP_INTERVAL b_, SCIP_INTERVAL x)
Definition: intervalarith.c:2730
void SCIPintervalSetRoundingModeUpwards(void)
Definition: intervalarith.c:278
void SCIPintervalExp(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2319
public methods for message output
#define CALCB(y)
SCIP_Real SCIPintervalPowerScalarIntegerSup(SCIP_Real operand1, int operand2)
Definition: intervalarith.c:1537
void SCIPintervalIntersect(SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:463
void SCIPintervalMulScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:982
void SCIPintervalSolveUnivariateQuadExpressionPositive(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL sqrcoeff, SCIP_INTERVAL lincoeff, SCIP_INTERVAL rhs, SCIP_INTERVAL xbnds)
Definition: intervalarith.c:2860
void SCIPintervalSetRoundingModeToNearest(void)
Definition: intervalarith.c:286
void SCIPintervalMulInf(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:723
void SCIPintervalSub(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:664
#define CALCR(c, y)
common defines and data types used in all packages of SCIP
void SCIPintervalAddScalar(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_Real operand2)
Definition: intervalarith.c:584
SCIP_ROUNDMODE SCIPintervalGetRoundingMode(void)
Definition: intervalarith.c:199
void SCIPintervalPower(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:1422
void SCIPintervalSetRoundingModeDownwards(void)
Definition: intervalarith.c:270
void SCIPintervalReciprocal(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand)
Definition: intervalarith.c:2246
void SCIPintervalPowerScalarInverse(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL basedomain, SCIP_Real exponent, SCIP_INTERVAL image)
Definition: intervalarith.c:1993
SCIP_Bool SCIPintervalIsSubsetEQ(SCIP_Real infinity, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:435
void SCIPintervalAddInf(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:503
void SCIPintervalScalprodScalarsSup(SCIP_Real infinity, SCIP_INTERVAL *resultant, int length, SCIP_INTERVAL *operand1, SCIP_Real *operand2)
Definition: intervalarith.c:1235
void SCIPintervalUnify(SCIP_INTERVAL *resultant, SCIP_INTERVAL operand1, SCIP_INTERVAL operand2)
Definition: intervalarith.c:476
void SCIPintervalQuad(SCIP_Real infinity, SCIP_INTERVAL *resultant, SCIP_Real sqrcoeff, SCIP_INTERVAL lincoeff, SCIP_INTERVAL xrng)
Definition: intervalarith.c:2825