Esempio n. 1
0
// Returns true and sets gap if a gap is generated, otherwise gap is undefined
bool extended_division(const interval& x, const interval& y, interval& z, interval& gap) {

	gap = interval();

	if (z.is_narrow()) { // if narrow, don't do anything
		// TODO Actually, feasibility could be checked
		return false;
	}

	if (!y.contains(0)) {  // trivial case

		z.intersect(x/y);

		return false;
	}
	// y.contains(0)==true

	if (x.contains(0)) {  // no progress case

		return false;
	}
	// (!x.contains(0) && y.contains(0)) == true

	if (y.inf()==0 && y.sup()==0) {  // undefined case
		// FIXME Is it safe to declare it infeasible? Or should we just signal no progress?
		//ASSERT2(false, "undefined result; x, z: "<<x<<", "<<z);
		throw infeasible_problem();
	}

	return true_extended_division(x, y, z, gap);
}
Esempio n. 2
0
interval interval::intersect( const interval& pOther ) const {
    if( !(*this).contains(pOther.mMin) && !(*this).contains(pOther.mMax) &&
            !pOther.contains(mMin) && !pOther.contains(mMax) ) {
        return interval( ggl::nan() );
    } else {
        return interval( std::max(mMin, pOther.mMin), std::min(mMax, pOther.mMax) );
    }
}
Esempio n. 3
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	void r_search(Node *root, const interval<T>& i, ivec& vec, int mode) {
		if (root == NULL) return;

		if (mode == OVERLAP && root->m_interval->overlaps(i)) vec.push_back(*(root->m_interval));
		if (mode == CONTAIN && root->m_interval->contains(i)) vec.push_back(*(root->m_interval));
		if (mode == CONTAINED && i.contains(*(root->m_interval))) vec.push_back(*(root->m_interval));

		if (root->left != NULL && i.overlaps(root->left->min, root->left->max))
			r_search(root->left, i, vec, mode);
		if (root->right != NULL && i.overlaps(root->right->min, root->right->max))
			r_search(root->right, i, vec, mode);
	}
Esempio n. 4
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bool true_extended_division(const interval& x, const interval& y, interval& z, interval& gap) {

	ASSERT(!x.contains(0) && y.contains(0));

	bool ret_val = false;

	if (x.ub < 0) {

		if (y.ub==0) {

			z.prechecked_intersection(x.ub/y.lb, z.ub);
		}
		else if (y.lb==0) {

			z.prechecked_intersection(z.lb, x.ub/y.ub);
		}
		else {

			ret_val = save_gap_if_any(x.ub/y.ub, x.ub/y.lb, z, gap);
		}
	}
	else {

		if (y.ub==0) {

			z.prechecked_intersection(z.lb, x.lb/y.lb);
		}
		else if (y.lb==0) {

			z.prechecked_intersection(x.lb/y.ub, z.ub);
		}
		else {

			ret_val = save_gap_if_any(x.lb/y.lb, x.lb/y.ub, z, gap);
		}
	}

	return ret_val;
}
Esempio n. 5
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void random_updater::shift_var(unsigned j, interval & r) {
    SASSERT(r.contains(m_core_solver.m_r_x[j]));
    SASSERT(m_core_solver.m_r_solver.column_is_feasible(j));
    auto old_x = m_core_solver.m_r_x[j];
    remove_value(old_x);
    auto new_val = m_core_solver.m_r_x[j] = get_random_from_interval(r);
    add_value(new_val);

    SASSERT(r.contains(m_core_solver.m_r_x[j]));
    SASSERT(m_core_solver.m_r_solver.column_is_feasible(j));
    auto delta = m_core_solver.m_r_x[j] - old_x;
   
    unsigned i;
    m_column_j->reset();
    mpq a;
    while(m_column_j->next(a, i)) {
        unsigned bj = m_core_solver.m_r_basis[i];
        m_core_solver.m_r_x[bj] -= a * delta;
        SASSERT(m_core_solver.m_r_solver.column_is_feasible(bj));
    }
    SASSERT(m_core_solver.m_r_solver.A_mult_x_is_off() == false);
}
Esempio n. 6
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const interval operator/(const interval& x, const interval& y) {

	ASSERT2(x.lb<=x.ub && y.lb<=y.ub, "x: "<<x<<", y: "<<y);

	ASSERT2(!y.contains(0), "y: "<<y);

	double z[] = { x.lb/y.lb, x.lb/y.ub, x.ub/y.lb, x.ub/y.ub };

	double zL = *std::min_element(z, z+4);

	double zU = *std::max_element(z, z+4);

	return interval(zL, zU);
}
Esempio n. 7
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 inline bool intersects (const interval & ot, cood eps = 0) const
 { return contains(ot.a, eps) || contains(ot.b, eps) || ot.contains(*this, eps); }