247 lines
7.2 KiB
C++
247 lines
7.2 KiB
C++
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#ifndef STAR_NET_ELEMENT_FLOAT_FIELDS_HPP
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#define STAR_NET_ELEMENT_FLOAT_FIELDS_HPP
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#include <type_traits>
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#include "StarNetElement.hpp"
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#include "StarInterpolation.hpp"
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namespace Star {
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STAR_EXCEPTION(StepStreamException, StarException);
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template <typename T>
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class NetElementFloating : public NetElement {
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public:
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T get() const;
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void set(T value);
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// If a fixed point base is given, then instead of transmitting the value as
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// a float, it is transmitted as a VLQ of the value divided by the fixed
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// point base. Any NetElementFloating that is transmitted to must also have
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// the same fixed point base set.
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void setFixedPointBase(Maybe<T> fixedPointBase = {});
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// If interpolation is enabled on the NetStepStates parent, and an
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// interpolator is set, then on steps in between data points this will be
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// used to interpolate this value. It is not necessary that senders and
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// receivers both have matching interpolation functions, or any interpolation
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// functions at all.
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void setInterpolator(function<T(T, T, T)> interpolator);
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void initNetVersion(NetElementVersion const* version = nullptr) override;
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// Values are never interpolated, but they will be delayed for the given
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// interpolationTime.
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void enableNetInterpolation(float extrapolationHint = 0.0f) override;
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void disableNetInterpolation() override;
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void tickNetInterpolation(float dt) override;
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void netStore(DataStream& ds) const override;
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void netLoad(DataStream& ds) override;
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bool writeNetDelta(DataStream& ds, uint64_t fromVersion) const override;
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void readNetDelta(DataStream& ds, float interpolationTime = 0.0f) override;
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void blankNetDelta(float interpolationTime = 0.0f) override;
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private:
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void writeValue(DataStream& ds, T t) const;
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T readValue(DataStream& ds) const;
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T interpolate() const;
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Maybe<T> m_fixedPointBase;
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NetElementVersion const* m_netVersion = nullptr;
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uint64_t m_latestUpdateVersion = 0;
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T m_value = T();
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function<T(T, T, T)> m_interpolator;
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float m_extrapolation = 0.0f;
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Maybe<Deque<pair<float, T>>> m_interpolationDataPoints;
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};
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typedef NetElementFloating<float> NetElementFloat;
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typedef NetElementFloating<double> NetElementDouble;
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template <typename T>
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T NetElementFloating<T>::get() const {
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return m_value;
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}
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template <typename T>
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void NetElementFloating<T>::set(T value) {
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if (m_value != value) {
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// Only mark the step as updated here if it actually would change the
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// transmitted value.
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if (!m_fixedPointBase || round(m_value / *m_fixedPointBase) != round(value / *m_fixedPointBase))
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m_latestUpdateVersion = m_netVersion ? m_netVersion->current() : 0;
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m_value = value;
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if (m_interpolationDataPoints) {
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m_interpolationDataPoints->clear();
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m_interpolationDataPoints->append({0.0f, m_value});
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}
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}
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}
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template <typename T>
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void NetElementFloating<T>::setFixedPointBase(Maybe<T> fixedPointBase) {
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m_fixedPointBase = fixedPointBase;
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}
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template <typename T>
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void NetElementFloating<T>::setInterpolator(function<T(T, T, T)> interpolator) {
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m_interpolator = move(interpolator);
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}
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template <typename T>
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void NetElementFloating<T>::initNetVersion(NetElementVersion const* version) {
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m_netVersion = version;
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m_latestUpdateVersion = 0;
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}
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template <typename T>
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void NetElementFloating<T>::enableNetInterpolation(float extrapolationHint) {
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m_extrapolation = extrapolationHint;
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if (!m_interpolationDataPoints) {
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m_interpolationDataPoints.emplace();
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m_interpolationDataPoints->append({0.0f, m_value});
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}
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}
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template <typename T>
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void NetElementFloating<T>::disableNetInterpolation() {
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if (m_interpolationDataPoints) {
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m_value = m_interpolationDataPoints->last().second;
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m_interpolationDataPoints.reset();
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}
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}
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template <typename T>
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void NetElementFloating<T>::tickNetInterpolation(float dt) {
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if (m_interpolationDataPoints) {
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for (auto& p : *m_interpolationDataPoints)
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p.first -= dt;
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while (m_interpolationDataPoints->size() > 2 && (*m_interpolationDataPoints)[1].first <= 0.0f)
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m_interpolationDataPoints->removeFirst();
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m_value = interpolate();
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}
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}
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template <typename T>
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void NetElementFloating<T>::netStore(DataStream& ds) const {
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if (m_interpolationDataPoints)
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writeValue(ds, m_interpolationDataPoints->last().second);
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else
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writeValue(ds, m_value);
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}
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template <typename T>
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void NetElementFloating<T>::netLoad(DataStream& ds) {
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m_value = readValue(ds);
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m_latestUpdateVersion = m_netVersion ? m_netVersion->current() : 0;
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if (m_interpolationDataPoints) {
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m_interpolationDataPoints->clear();
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m_interpolationDataPoints->append({0.0f, m_value});
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}
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}
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template <typename T>
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bool NetElementFloating<T>::writeNetDelta(DataStream& ds, uint64_t fromVersion) const {
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if (m_latestUpdateVersion < fromVersion)
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return false;
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if (m_interpolationDataPoints)
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writeValue(ds, m_interpolationDataPoints->last().second);
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else
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writeValue(ds, m_value);
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return true;
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}
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template <typename T>
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void NetElementFloating<T>::readNetDelta(DataStream& ds, float interpolationTime) {
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T t = readValue(ds);
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m_latestUpdateVersion = m_netVersion ? m_netVersion->current() : 0;
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if (m_interpolationDataPoints) {
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if (interpolationTime < m_interpolationDataPoints->last().first)
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m_interpolationDataPoints->clear();
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m_interpolationDataPoints->append({interpolationTime, t});
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m_value = interpolate();
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} else {
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m_value = t;
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}
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}
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template <typename T>
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void NetElementFloating<T>::blankNetDelta(float interpolationTime) {
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if (m_interpolationDataPoints) {
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auto lastPoint = m_interpolationDataPoints->last();
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float lastTime = lastPoint.first;
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lastPoint.first = interpolationTime;
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if (interpolationTime < lastTime)
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*m_interpolationDataPoints = {lastPoint};
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else
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m_interpolationDataPoints->append(lastPoint);
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m_value = interpolate();
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}
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}
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template <typename T>
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void NetElementFloating<T>::writeValue(DataStream& ds, T t) const {
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if (m_fixedPointBase)
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ds.writeVlqI(round(t / *m_fixedPointBase));
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else
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ds.write(t);
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}
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template <typename T>
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T NetElementFloating<T>::readValue(DataStream& ds) const {
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T t;
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if (m_fixedPointBase)
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t = ds.readVlqI() * *m_fixedPointBase;
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else
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ds.read(t);
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return t;
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}
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template <typename T>
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T NetElementFloating<T>::interpolate() const {
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auto& dataPoints = *m_interpolationDataPoints;
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float ipos = inverseLinearInterpolateUpper(dataPoints.begin(), dataPoints.end(), 0.0f,
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[](float lhs, auto const& rhs) {
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return lhs < rhs.first;
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}, [](auto const& dataPoint) {
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return dataPoint.first;
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});
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auto bound = getBound2(ipos, dataPoints.size(), BoundMode::Extrapolate);
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if (m_interpolator) {
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auto const& minPoint = dataPoints[bound.i0];
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auto const& maxPoint = dataPoints[bound.i1];
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// If step separation is less than 1.0, don't normalize extrapolation to
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// the very small step difference, because this can result in large jumps
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// during jitter.
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float stepDist = max(maxPoint.first - minPoint.first, 1.0f);
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float offset = clamp<float>(bound.offset, 0.0f, 1.0f + m_extrapolation / stepDist);
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return m_interpolator(offset, minPoint.second, maxPoint.second);
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} else {
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if (bound.offset < 1.0f)
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return dataPoints[bound.i0].second;
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else
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return dataPoints[bound.i1].second;
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}
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}
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}
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#endif
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