MediaTime::ComparisonFlags MediaTime::compare(const MediaTime& rhs, bool fuzzy) const
{
if ((isPositiveInfinite() && rhs.isPositiveInfinite())
|| (isNegativeInfinite() && rhs.isNegativeInfinite())
|| (isInvalid() && rhs.isInvalid())
|| (isIndefinite() && rhs.isIndefinite()))
return EqualTo;
if (isInvalid())
return GreaterThan;
if (rhs.isInvalid())
return LessThan;
if (rhs.isNegativeInfinite() || isPositiveInfinite())
return GreaterThan;
if (rhs.isPositiveInfinite() || isNegativeInfinite())
return LessThan;
if (isIndefinite())
return GreaterThan;
if (rhs.isIndefinite())
return LessThan;
if (hasDoubleValue() && rhs.hasDoubleValue()) {
if (m_timeValueAsDouble == rhs.m_timeValueAsDouble)
return EqualTo;
if (fuzzy && fabs(m_timeValueAsDouble - rhs.m_timeValueAsDouble) <= fuzzinessThreshold().toDouble())
return EqualTo;
return m_timeValueAsDouble < rhs.m_timeValueAsDouble ? LessThan : GreaterThan;
}
MediaTime a = *this;
MediaTime b = rhs;
if (a.hasDoubleValue())
a.setTimeScale(DefaultTimeScale);
if (b.hasDoubleValue())
b.setTimeScale(DefaultTimeScale);
int64_t rhsWhole = b.m_timeValue / b.m_timeScale;
int64_t lhsWhole = a.m_timeValue / a.m_timeScale;
if (lhsWhole > rhsWhole)
return GreaterThan;
if (lhsWhole < rhsWhole)
return LessThan;
int64_t rhsRemain = b.m_timeValue % b.m_timeScale;
int64_t lhsRemain = a.m_timeValue % a.m_timeScale;
int64_t lhsFactor = lhsRemain * b.m_timeScale;
int64_t rhsFactor = rhsRemain * a.m_timeScale;
if (lhsFactor == rhsFactor)
return EqualTo;
return lhsFactor > rhsFactor ? GreaterThan : LessThan;
}
double MediaTime::toDouble() const
{
if (isInvalid() || isIndefinite())
return std::numeric_limits<double>::quiet_NaN();
if (isPositiveInfinite())
return std::numeric_limits<double>::infinity();
if (isNegativeInfinite())
return -std::numeric_limits<double>::infinity();
return static_cast<double>(m_timeValue) / m_timeScale;
}
MediaTime::ComparisonFlags MediaTime::compare(const MediaTime& rhs) const
{
if ((isPositiveInfinite() && rhs.isPositiveInfinite())
|| (isNegativeInfinite() && rhs.isNegativeInfinite())
|| (isInvalid() && rhs.isInvalid())
|| (isIndefinite() && rhs.isIndefinite()))
return EqualTo;
if (isInvalid())
return GreaterThan;
if (rhs.isInvalid())
return LessThan;
if (rhs.isNegativeInfinite() || isPositiveInfinite())
return GreaterThan;
if (rhs.isPositiveInfinite() || isNegativeInfinite())
return LessThan;
if (isIndefinite())
return GreaterThan;
if (rhs.isIndefinite())
return LessThan;
int64_t rhsWhole = rhs.m_timeValue / rhs.m_timeScale;
int64_t lhsWhole = m_timeValue / m_timeScale;
if (lhsWhole > rhsWhole)
return GreaterThan;
if (lhsWhole < rhsWhole)
return LessThan;
int64_t rhsRemain = rhs.m_timeValue % rhs.m_timeScale;
int64_t lhsRemain = m_timeValue % m_timeScale;
int64_t lhsFactor = lhsRemain * rhs.m_timeScale;
int64_t rhsFactor = rhsRemain * m_timeScale;
if (lhsFactor == rhsFactor)
return EqualTo;
return lhsFactor > rhsFactor ? GreaterThan : LessThan;
}
float MediaTime::toFloat() const
{
if (isInvalid() || isIndefinite())
return std::numeric_limits<float>::quiet_NaN();
if (isPositiveInfinite())
return std::numeric_limits<float>::infinity();
if (isNegativeInfinite())
return -std::numeric_limits<float>::infinity();
if (hasDoubleValue())
return m_timeValueAsDouble;
return static_cast<float>(m_timeValue) / m_timeScale;
}
MediaTime MediaTime::operator-(const MediaTime& rhs) const
{
if (rhs.isInvalid() || isInvalid())
return invalidTime();
if (rhs.isIndefinite() || isIndefinite())
return indefiniteTime();
if (isPositiveInfinite() && rhs.isPositiveInfinite())
return invalidTime();
if (isNegativeInfinite() && rhs.isNegativeInfinite())
return invalidTime();
if (isPositiveInfinite() || rhs.isNegativeInfinite())
return positiveInfiniteTime();
if (isNegativeInfinite() || rhs.isPositiveInfinite())
return negativeInfiniteTime();
if (hasDoubleValue() && rhs.hasDoubleValue())
return MediaTime::createWithDouble(m_timeValueAsDouble - rhs.m_timeValueAsDouble);
MediaTime a = *this;
MediaTime b = rhs;
if (a.hasDoubleValue())
a.setTimeScale(DefaultTimeScale);
else if (b.hasDoubleValue())
b.setTimeScale(DefaultTimeScale);
int32_t commonTimeScale;
if (!leastCommonMultiple(this->m_timeScale, rhs.m_timeScale, commonTimeScale) || commonTimeScale > MaximumTimeScale)
commonTimeScale = MaximumTimeScale;
a.setTimeScale(commonTimeScale);
b.setTimeScale(commonTimeScale);
while (!safeSub(a.m_timeValue, b.m_timeValue, a.m_timeValue)) {
if (commonTimeScale == 1)
return a.m_timeValue > 0 ? positiveInfiniteTime() : negativeInfiniteTime();
commonTimeScale /= 2;
a.setTimeScale(commonTimeScale);
b.setTimeScale(commonTimeScale);
}
return a;
}
MediaTime MediaTime::operator-() const
{
if (isInvalid())
return invalidTime();
if (isIndefinite())
return indefiniteTime();
if (isPositiveInfinite())
return negativeInfiniteTime();
if (isNegativeInfinite())
return positiveInfiniteTime();
MediaTime negativeTime = *this;
if (negativeTime.hasDoubleValue())
negativeTime.m_timeValueAsDouble = -negativeTime.m_timeValueAsDouble;
else
negativeTime.m_timeValue = -negativeTime.m_timeValue;
return negativeTime;
}
MediaTime MediaTime::operator*(int32_t rhs) const
{
if (isInvalid())
return invalidTime();
if (isIndefinite())
return indefiniteTime();
if (!rhs)
return zeroTime();
if (isPositiveInfinite()) {
if (rhs > 0)
return positiveInfiniteTime();
return negativeInfiniteTime();
}
if (isNegativeInfinite()) {
if (rhs > 0)
return negativeInfiniteTime();
return positiveInfiniteTime();
}
MediaTime a = *this;
if (a.hasDoubleValue()) {
a.m_timeValueAsDouble *= rhs;
return a;
}
while (!safeMultiply(a.m_timeValue, rhs, a.m_timeValue)) {
if (a.m_timeScale == 1)
return signum(a.m_timeValue) == signum(rhs) ? positiveInfiniteTime() : negativeInfiniteTime();
a.setTimeScale(a.m_timeScale / 2);
}
return a;
}
MediaTime MediaTime::operator-(const MediaTime& rhs) const
{
if (rhs.isInvalid() || isInvalid())
return invalidTime();
if (rhs.isIndefinite() || isIndefinite())
return indefiniteTime();
if (isPositiveInfinite()) {
if (rhs.isPositiveInfinite())
return invalidTime();
return positiveInfiniteTime();
}
if (isNegativeInfinite()) {
if (rhs.isNegativeInfinite())
return invalidTime();
return negativeInfiniteTime();
}
int32_t commonTimeScale;
if (!leastCommonMultiple(this->m_timeScale, rhs.m_timeScale, commonTimeScale) || commonTimeScale > MaximumTimeScale)
commonTimeScale = MaximumTimeScale;
MediaTime a = *this;
MediaTime b = rhs;
a.setTimeScale(commonTimeScale);
b.setTimeScale(commonTimeScale);
while (!safeSub(a.m_timeValue, b.m_timeValue, a.m_timeValue)) {
if (commonTimeScale == 1)
return a.m_timeValue > 0 ? positiveInfiniteTime() : negativeInfiniteTime();
commonTimeScale /= 2;
a.setTimeScale(commonTimeScale);
b.setTimeScale(commonTimeScale);
}
return a;
}
