Struct moc::hpxranges2d::HpxRanges2D

pub struct HpxRanges2D<TT: Idx, T: MocQty<TT>, ST: Idx>(pub Moc2DRanges<TT, T, ST, Hpx<ST>>);

Tuple Fields

0: Moc2DRanges<TT, T, ST, Hpx<ST>>

Implementations

impl<TT: Idx> HpxRanges2D<TT, Time<TT>, TT>

pub fn time_space_iter(
    &self,
    depth_max_t: u8,
    depth_max_s: u8
) -> TimeSpaceRangesIter<'_, TT>

pub fn from_ranges_it<I>(it: I) -> Self where
    I: RangeMOC2Iterator<TT, Time<TT>, RangeMocIter<TT, Time<TT>>, TT, Hpx<TT>, RangeMocIter<TT, Hpx<TT>>, RangeMOC2Elem<TT, Time<TT>, TT, Hpx<TT>>>, 

pub fn from_ranges_it_gen<I, J, K, L>(it: L) -> Self where
    I: RangeMOCIterator<TT, Qty = Time<TT>>,
    J: RangeMOCIterator<TT, Qty = Hpx<TT>>,
    K: RangeMOC2ElemIt<TT, Time<TT>, TT, Hpx<TT>, It1 = I, It2 = J>,
    L: RangeMOC2Iterator<TT, Time<TT>, I, TT, Hpx<TT>, J, K>, 

impl<TT, T, ST> HpxRanges2D<TT, T, ST> where
    TT: Idx,
    T: MocQty<TT>,
    ST: Idx, 

pub fn create_from_times_positions(
    x: Vec<TT>,
    y: Vec<ST>,
    d1: u8,
    d2: u8
) -> HpxRanges2D<TT, T, ST>

Create a Quantity/Space 2D coverage

Arguments

• x - A set of values expressed that will be converted to ranges and degraded at the depth d1. This quantity axe may refer to a time (expressed in µs), a redshift etc… This will define the first dimension of the coverage.
• y - A set of spatial HEALPix cell indices at the depth d2. This will define the second dimension of the coverage.
• d1 - The depth of the coverage along its 1st dimension.
• d2 - The depth of the coverage along its 2nd dimension.

The resulted 2D coverage will be of depth (d1, d2)

Precondition

• d1 must be valid (within [0, <T>::MAXDEPTH])
• d2 must be valid (within [0, <S>::MAXDEPTH])
• x and y must have the same size.

pub fn create_from_time_ranges_positions(
    x: Vec<Range<TT>>,
    y: Vec<ST>,
    d1: u8,
    d2: u8
) -> HpxRanges2D<TT, T, ST>

Create a Quantity/Space 2D coverage

Arguments

• x - A set of quantity ranges that will be degraded to the depth d1. This quantity axe may refer to a time (expressed in µs), a redshift etc… This will define the first dimension of the coverage.
• y - A set of spatial HEALPix cell indices at the depth d2. This will define the second dimension of the coverage.
• d2 - The depth of the coverage along its 2nd dimension.

The resulted 2D coverage will be of depth (d1, d2)

Precondition

• d2 must be valid (within [0, <S>::MAXDEPTH])
• x and y must have the same size.
• x must contain [a..b] ranges where b > a.

pub fn create_from_time_ranges_spatial_coverage(
    x: Vec<Range<TT>>,
    y: Vec<HpxRanges<ST>>,
    d1: u8
) -> HpxRanges2D<TT, T, ST>

Create a Quantity/Space 2D coverage

Arguments

• x - A set of quantity ranges that will be degraded to the depth d1. This quantity axe may refer to a time (expressed in µs), a redshift etc… This will define the first dimension of the coverage.
• y - A set of spatial HEALPix cell indices at the depth d2. This will define the second dimension of the coverage.
• d2 - The depth of the coverage along its 2nd dimension.

The resulted 2D coverage will be of depth (d1, d2)

Precondition

• d2 must be valid (within [0, <S>::MAXDEPTH])
• x and y must have the same size.
• x must contain [a..b] ranges where b > a.

pub fn project_on_second_dim(
    x: &MocRanges<TT, T>,
    coverage: &HpxRanges2D<TT, T, ST>
) -> HpxRanges<ST>

Returns the union of the ranges along the S axis for which their T ranges intersect x

Arguments

• x- The set of ranges along the T axis.
• coverage - The input coverage

Algorithm

This method checks for all the T axis ranges of coverage that lie into the range set x.

It then performs the union of the S axis ranges corresponding to the matching ranges along the T axis.

pub fn project_on_first_dim(
    y: &HpxRanges<ST>,
    coverage: &HpxRanges2D<TT, T, ST>
) -> MocRanges<TT, T>

Returns the union of the ranges along the T axis for which their S ranges is contained in y

Arguments

• y- The set of ranges along the S axis.
• coverage - The input coverage.

Algorithm

This method checks for all the S axis ranges of coverage that lie into the range set y.

It then performs the union of the T axis ranges corresponding to the matching ranges along the S axis.

pub fn compute_min_depth(&self) -> (u8, u8)

Compute the depth of the coverage

Returns

A tuple containing two values:

• The maximum depth along the T axis
• The maximum depth along the S axis

Info

If the NestedRanges2D<T, S> is empty, the depth returned is set to (0, 0)

pub fn t_min(&self) -> Result<TT, &'static str>

Returns the minimum value along the T dimension

Errors

When the NestedRanges2D<T, S> is empty.

pub fn t_max(&self) -> Result<TT, &'static str>

Returns the maximum value along the T dimension

Errors

When the NestedRanges2D<T, S> is empty.

pub fn union(&self, other: &Self) -> Self

Performs the union between two NestedRanges2D<T, S>

Arguments

• other - The other NestedRanges2D<T, S> to perform the union with.

pub fn intersection(&self, other: &Self) -> Self

Performs the intersection between two NestedRanges2D<T, S>

Arguments

• other - The other NestedRanges2D<T, S> to perform the intersection with.

pub fn difference(&self, other: &Self) -> Self

Performs the difference between two NestedRanges2D<T, S>

Arguments

• other - The other NestedRanges2D<T, S> to perform the difference with.

pub fn contains(&self, time: TT, range: &Range<ST>) -> bool

Check whether a NestedRanges2D<T, S> has data in a (time, ra, dec) tuple.

Arguments

• time - The time of the tuple
• range - The position that has been converted to a nested range

pub fn is_empty(&self) -> bool

Check whether a NestedRanges2D<T, S> is empty

Trait Implementations

impl<TT: Debug + Idx, T: Debug + MocQty<TT>, ST: Debug + Idx> Debug for HpxRanges2D<TT, T, ST>

fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter.

impl<TT, T, ST> Default for HpxRanges2D<TT, T, ST> where
    TT: Idx,
    T: MocQty<TT>,
    ST: Idx, 

fn default() -> HpxRanges2D<TT, T, ST>

Create a new empty NestedRanges2D<T, S>

impl From<CellMoc2Iter<u64, Time<u64>, u64, Hpx<u64>>> for HpxRanges2D<u64, Time<u64>, u64>

fn from(it: CellMoc2Iter<u64, Time<u64>, u64, Hpx<u64>>) -> Self

Performs the conversion.

impl From<CellOrCellRangeMoc2Iter<u64, Time<u64>, u64, Hpx<u64>>> for HpxRanges2D<u64, Time<u64>, u64>

fn from(it: CellOrCellRangeMoc2Iter<u64, Time<u64>, u64, Hpx<u64>>) -> Self

Performs the conversion.

impl<TT, T, ST> PartialEq<HpxRanges2D<TT, T, ST>> for HpxRanges2D<TT, T, ST> where
    TT: Idx,
    T: MocQty<TT>,
    ST: Idx, 

fn eq(&self, other: &Self) -> bool

This method tests for self and other values to be equal, and is used by ==.

fn ne(&self, other: &Rhs) -> bool

This method tests for !=.

impl<TT, T, ST> Eq for HpxRanges2D<TT, T, ST> where
    TT: Idx,
    T: MocQty<TT>,
    ST: Idx,