Series
is an immutable container for 1D homogeneous data which is indexed
by a an associated sequence of keys.
Both the index and value data are backed by arrays.
Series
is effectively an associative map whose keys have an ordering
provided by the natural (provided) order of the backing array.
Several element access methods are provided.
The apply
method returns a slice of the original Series:
val s = Series(Vec(1,2,3,4), Index('a','b','b','c'))
s('a') == Series('a'->1)
s('b') == Series('b'->2, 'b'->3)
Other ways to slice a series involve implicitly constructing an org.saddle.index.Slice object and passing it to the Series apply method:
s('a'->'b') == Series('a'->1, 'b'->2, 'b'->3)
s(* -> 'b') == Series('a'->1, 'b'->2, 'b'->3)
s('b' -> *) == Series('b'->2, 'b'->3, 'c'->4)
s(*) == s
The at
method returns an instance of a org.saddle.scalar.Scalar, which
behaves much like an Option
in that it can be either an instance of
org.saddle.scalar.NA or a org.saddle.scalar.Value case class:
s.at(0) == Scalar(1)
The slice
method allows slicing the Series for locations in [i, j)
irrespective of the value of the keys at those locations.
s.slice(2,4) == Series('b'->3, 'c'->4)
To slice explicitly by labels, use the sliceBy
method, which is inclusive
of the key boundaries:
s.sliceBy('b','c') == Series('b'->3, 'c'->4)
The method raw
accesses the value directly, which may reveal the
underlying representation of a missing value (so be careful).
s.raw(0) == 1
Series
may be used in arithmetic expressions which operate on two Series
or on a Series
and a scalar value. In the former case, the two Series will
automatically align along their indexes. A few examples:
s * 2 == Series('a'->2, 'b'->4, ... )
s + s.shift(1) == Series('a'->NA, 'b'->3, 'b'->5, ...)
Attributes
- T
Type of elements in the values array, for which there must be an implicit ST
- X
Type of elements in the index, for which there must be an implicit Ordering and ST
- index
Index backing the keys in the Series
- values
Vec backing the values in the Series
- Companion:
- object
- Graph
- Supertypes
Members list
Value members
Concrete methods
Aligns this series with another series, returning the two series aligned to each others indexes according to the the provided parameter
Aligns this series with another series, returning the two series aligned to each others indexes according to the the provided parameter
Attributes
- how
How to perform the join on the indexes
- other
Other series to align with
Extract a Series corresponding to those keys provided. Returns a new Series whose key-value pairs maintain the original ordering.
Extract a Series corresponding to those keys provided. Returns a new Series whose key-value pairs maintain the original ordering.
Attributes
- keys
Array of keys
Extract a Series corresponding to those keys provided. Returns a new Series whose key-value pairs maintain the original ordering.
Extract a Series corresponding to those keys provided. Returns a new Series whose key-value pairs maintain the original ordering.
Attributes
- keys
Sequence of keys
Extract a Series whose keys respect the Slice provided. Returns a new Series whose key-value pairs maintain the original ordering.
Extract a Series whose keys respect the Slice provided. Returns a new Series whose key-value pairs maintain the original ordering.
Attributes
- slice
Slice
Access a boxed element of a Series at a single location
Access a boxed element of a Series at a single location
Attributes
- loc
offset into Series
Access multiple locations of a Series, returning a new Series comprising those locations
Access multiple locations of a Series, returning a new Series comprising those locations
Attributes
- locs
Array of int offsets into Series
Access multiple locations of a Series, returning a new Series comprising those locations
Access multiple locations of a Series, returning a new Series comprising those locations
Attributes
- locs
Sequence of Int
Concatenate two Series instances together whose indexes share the same
type of element, and where there exists some way to join the values of the
Series. For instance, Series[X, Double] concat
Series[X, Int] will
promote Int to Double as a result of the implicit existence of a
Promoter[Double, Int, Double] instance. The result Index will simply be
the concatenation of the two input Indexes.
Concatenate two Series instances together whose indexes share the same
type of element, and where there exists some way to join the values of the
Series. For instance, Series[X, Double] concat
Series[X, Int] will
promote Int to Double as a result of the implicit existence of a
Promoter[Double, Int, Double] instance. The result Index will simply be
the concatenation of the two input Indexes.
Attributes
- U
type of other Series Values
- V
type of resulting Series values
- md
Implicit evidence of ST[C]
- other
Series[X, B] to concat
- pro
Implicit evidence of Promoter[A, B, C]
Returns true if the index of the Series contains the key
Returns true if the index of the Series contains the key
Attributes
- key
The key to check
Return the series with the first occurence of each key
Return the series with the first occurence of each key
Attributes
Creates a Series having the same values but excluding all key/value pairs in which the value is NA.
Creates a Series having the same values but excluding all key/value pairs in which the value is NA.
Attributes
Compares the receiver object (this
) with the argument object (that
) for equivalence.
Compares the receiver object (this
) with the argument object (that
) for equivalence.
Any implementation of this method should be an equivalence relation:
- It is reflexive: for any instance
x
of typeAny
,x.equals(x)
should returntrue
. - It is symmetric: for any instances
x
andy
of typeAny
,x.equals(y)
should returntrue
if and only ify.equals(x)
returnstrue
. - It is transitive: for any instances
x
,y
, andz
of typeAny
ifx.equals(y)
returnstrue
andy.equals(z)
returnstrue
, thenx.equals(z)
should returntrue
.
If you override this method, you should verify that your implementation remains an equivalence relation.
Additionally, when overriding this method it is usually necessary to override hashCode
to ensure that
objects which are "equal" (o1.equals(o2)
returns true
) hash to the same scala.Int.
(o1.hashCode.equals(o2.hashCode)
).
Attributes
- that
the object to compare against this object for equality.
- Returns:
true
if the receiver object is equivalent to the argument;false
otherwise.- Definition Classes
- Any
Return true if there exists some element of the Series which satisfies the predicate function
Return true if there exists some element of the Series which satisfies the predicate function
Attributes
- pred
Predicate function from T => Boolean
Fill NA values by propagating defined values backward.
Fill NA values by propagating defined values backward.
Attributes
- limit
If > 0, propagate over a maximum of
limit
consecutive NA values.
Fill NA values by propagating defined values forward.
Fill NA values by propagating defined values forward.
Attributes
- limit
If > 0, propagate over a maximum of
limit
consecutive NA values.
Fill NA values in series with result of a function which acts on the index of the particular NA value found.
Fill NA values in series with result of a function which acts on the index of the particular NA value found.
Attributes
- f
A function X => A to be applied at NA location
Fill NA values by propagating defined values.
Fill NA values by propagating defined values.
Attributes
- limit
If > 0, propagate over a maximum of
limit
consecutive NA values.
Return Series whose values satisfy a predicate function
Return Series whose values satisfy a predicate function
Attributes
- pred
Predicate function from T => Boolean
Return Series whose offets satisfy a predicate function
Return Series whose offets satisfy a predicate function
Attributes
- pred
Predicate function from Int => Boolean
Return Series whose index keys satisfy a predicate function
Return Series whose index keys satisfy a predicate function
Attributes
- pred
Predicate function from X => Boolean
Search for the int offsets where the values of the Series satisfy a predicate function.
Search for the int offsets where the values of the Series satisfy a predicate function.
Attributes
- pred
Function from T to Boolean
Search for the keys of the Series index whose corresponding values satisfy a predicate function.
Search for the keys of the Series index whose corresponding values satisfy a predicate function.
Attributes
- pred
Function from T to Boolean
Find the first int offset (or -1 if none) where a value of the Series satisfies a predicate function.
Find the first int offset (or -1 if none) where a value of the Series satisfies a predicate function.
Attributes
- pred
Function from T to Boolean
Find the first key (or NA if none) where a value of the Series satisfies a predicate function.
Find the first key (or NA if none) where a value of the Series satisfies a predicate function.
Attributes
- pred
Function from T to Boolean
Get the first value of the Series whose key matches that provided
Get the first value of the Series whose key matches that provided
Attributes
- key
Key on which to match
Map and then flatten over the key-value pairs of the Series, resulting in a new Series.
Map and then flatten over the key-value pairs of the Series, resulting in a new Series.
Attributes
Alias for first
. If a key exists, get the value associated with the
first occurrence of that key.
Alias for first
. If a key exists, get the value associated with the
first occurrence of that key.
Attributes
Construct a org.saddle.groupby.SeriesGrouper with which further computations, such as combine or transform, may be performed. The groups are constructed from the keys of the index, with each unique key corresponding to a group.
Construct a org.saddle.groupby.SeriesGrouper with which further computations, such as combine or transform, may be performed. The groups are constructed from the keys of the index, with each unique key corresponding to a group.
Attributes
Construct a org.saddle.groupby.SeriesGrouper with which further computations, such as combine or transform, may be performed. The groups are constructed from the result of the function applied to the keys of the Index; each unique result of calling the function on elements of the Index corresponds to a group.
Construct a org.saddle.groupby.SeriesGrouper with which further computations, such as combine or transform, may be performed. The groups are constructed from the result of the function applied to the keys of the Index; each unique result of calling the function on elements of the Index corresponds to a group.
Attributes
- Y
Type of function codomain
- fn
Function from X => Y
Construct a org.saddle.groupby.SeriesGrouper with which further computations, such as combine or transform, may be performed. The groups are constructed from the keys of the provided index, with each unique key corresponding to a group.
Construct a org.saddle.groupby.SeriesGrouper with which further computations, such as combine or transform, may be performed. The groups are constructed from the keys of the provided index, with each unique key corresponding to a group.
Attributes
- Y
Type of elements of ix
- ix
Index with which to perform grouping
Return true if there is at least one NA value in the Series
Return true if there is at least one NA value in the Series
Attributes
Calculate a hash code value for the object.
Calculate a hash code value for the object.
The default hashing algorithm is platform dependent.
Note that it is allowed for two objects to have identical hash codes (o1.hashCode.equals(o2.hashCode)
) yet
not be equal (o1.equals(o2)
returns false
). A degenerate implementation could always return 0
.
However, it is required that if two objects are equal (o1.equals(o2)
returns true
) that they have
identical hash codes (o1.hashCode.equals(o2.hashCode)
). Therefore, when overriding this method, be sure
to verify that the behavior is consistent with the equals
method.
Attributes
- Returns:
the hash code value for this object.
- Definition Classes
- Any
Extract at most the first n elements of the Series
Extract at most the first n elements of the Series
Attributes
- n
Number of elements to extract
True if and only if number of elements is zero
True if and only if number of elements is zero
Attributes
Perform a join with another Series[X, T] according to its index. The how
argument dictates how the join is to be performed:
Perform a join with another Series[X, T] according to its index. The how
argument dictates how the join is to be performed:
- Left org.saddle.index.LeftJoin
- Right org.saddle.index.RightJoin
- Inner org.saddle.index.InnerJoin
- Outer org.saddle.index.OuterJoin
The result is a Frame whose index is the result of the join, and whose column index is {0, 1}, and whose values are sourced from the original Series.
Attributes
- how
How to perform the join
- other
Series to join with
Perform a join with a Frame[X, _, T] according to its row index. The values of the other Frame must have the same type as the Series. The result is a Frame whose row index is the result of the join, and whose column index is [0, N), corresponding to the number of columns of the frame plus 1, and whose values are sourced from the original Series and Frame.
Perform a join with a Frame[X, _, T] according to its row index. The values of the other Frame must have the same type as the Series. The result is a Frame whose row index is the result of the join, and whose column index is [0, N), corresponding to the number of columns of the frame plus 1, and whose values are sourced from the original Series and Frame.
Attributes
- how
How to perform the join
- other
Frame[X, Any, T]
Join two series on their index and apply a function to each paired value; when either value is NA, the result of the function is forced to be NA.
Join two series on their index and apply a function to each paired value; when either value is NA, the result of the function is forced to be NA.
Attributes
- U
Type of other series values
- V
The result type of the function
- f
The function to apply
- how
The type of join to effect
- other
Other series
Access a boxed element of a Series index at a single location
Access a boxed element of a Series index at a single location
Attributes
- loc
offset into Series
Access a multiple locations of a Series index, returning a new Index
Access a multiple locations of a Series index, returning a new Index
Attributes
- locs
array of int offset into Index
Access a multiple locations of a Series index, returning a new Index
Access a multiple locations of a Series index, returning a new Index
Attributes
- locs
Sequence of int offsets into Index
Get the last value of the Series whose key matches that provided
Get the last value of the Series whose key matches that provided
Attributes
- key
Key on which to match
The length shared by both the index and the values array
The length shared by both the index and the values array
Attributes
Map over the key-value pairs of the Series, resulting in a new Series. Applies a function to each pair of values in the series.
Map over the key-value pairs of the Series, resulting in a new Series. Applies a function to each pair of values in the series.
Attributes
- U
The type of the resulting values
- Y
The type of the resulting index
- f
Function from (X,T) to (Y,U)
Map a function over the index, resulting in a new Series
Map a function over the index, resulting in a new Series
Attributes
- Y
Result type of index, ie Index[Y]
- fn
The function X => Y with which to map
Map over the values of the Series, resulting in a new Series. Applies a function to each (non-na) value in the series, returning a new series whose index remains the same.
Map over the values of the Series, resulting in a new Series. Applies a function to each (non-na) value in the series, returning a new series whose index remains the same.
Attributes
- U
The type of the resulting values
- f
Function from T to U
Map a function over the contents, resulting in a new Series
Map a function over the contents, resulting in a new Series
Attributes
- Y
Result type of index, ie Index[Y]
- fn
The function T => Y with which to map
Create a new Series that, wherever the mask Vec is true, is masked with NA
Create a new Series that, wherever the mask Vec is true, is masked with NA
Attributes
- m
Mask Vec[Boolean]
Create a new Series that, whenever the mask predicate function evaluates to true on a value, is masked with NA
Create a new Series that, whenever the mask predicate function evaluates to true on a value, is masked with NA
Attributes
- f
Function from T to Boolean
Create a new Series that, whenever the mask predicate function evaluates to true on a key, is masked with NA
Create a new Series that, whenever the mask predicate function evaluates to true on a key, is masked with NA
Attributes
- f
Function from X to Boolean
Return key corresponding to maximum value in series
Return key corresponding to maximum value in series
Attributes
Return key corresponding to minimum value in series
Return key corresponding to minimum value in series
Attributes
Pivot splits an index of tuple keys of arity N into a row index having arity N-1 and a column index, producing a 2D Frame whose values are from the original Series as indexed by the corresponding keys.
Pivot splits an index of tuple keys of arity N into a row index having arity N-1 and a column index, producing a 2D Frame whose values are from the original Series as indexed by the corresponding keys.
To recover the original Series, the melt method of Frame may be used.
For example, given:
Series(Vec(1,2,3,4), Index(('a',1),('a',2),('b',1),('b',2)))
res0: org.saddle.Series[(Char, Int),Int] =
[4 x 1]
a 1 => 1
2 => 2
b 1 => 3
2 => 4
the pivot command does the following:
res0.pivot
res1: org.saddle.Frame[Char,Int,Int] =
[2 x 2]
1 2
-- --
a => 1 2
b => 3 4
Attributes
- O1
Output row index
- O2
Output col index
- m1
Implicit evidence of a ST for O1
- m2
Implicit evidence of a ST for O2
- ord1
Implicit evidence of an ordering for O1
- ord2
Implicit evidence of an ordering for O2
- split
Implicit evidence of a Splitter for the index
Pretty-printer for Series, which simply outputs the result of stringify.
Pretty-printer for Series, which simply outputs the result of stringify.
Attributes
- len
Number of elements to display
Fill series NA's with values using a secondary series
Fill series NA's with values using a secondary series
Attributes
- proxy
The series containing the values to use
Access an unboxed element of a Series at a single location
Access an unboxed element of a Series at a single location
Attributes
- loc
offset into Series
Create a new Series whose index is the provided argument, and whose values are derived from the original Series.
Create a new Series whose index is the provided argument, and whose values are derived from the original Series.
Attributes
- newIx
Index of the result series
Create a new Series whose index is formed of the provided argument, and whose values are derived from the original Series.
Create a new Series whose index is formed of the provided argument, and whose values are derived from the original Series.
Attributes
- keys
Sequence of keys to be the index of the result series
Create a new Series whose index is newIx
and whose values are derived
from the original Series. For keys in newIx
not contained in this
series's index, the associated values are derived based on the filling
method fillMethod
against this series. This series must be monotonic,
othrwise IllegalArgumentException is thrown.
Create a new Series whose index is newIx
and whose values are derived
from the original Series. For keys in newIx
not contained in this
series's index, the associated values are derived based on the filling
method fillMethod
against this series. This series must be monotonic,
othrwise IllegalArgumentException is thrown.
Attributes
- fillMethod
Filling method to derive unfound keys of
newId
in this series.FillForward
orFillBackward
.- keys
Sequence of keys to be the index of the result series
- limit
Limit for the filling method. Not applicable if <= 0.
Create a new Series whose values are the same, but whose Index has been changed to the bound [0, length - 1), as in an array.
Create a new Series whose values are the same, but whose Index has been changed to the bound [0, length - 1), as in an array.
Attributes
Create a new Series whose values and index keys are both in reversed order
Create a new Series whose values and index keys are both in reversed order
Attributes
Produce a Series whose values are the result of executing a function on a sliding window of the data.
Produce a Series whose values are the result of executing a function on a sliding window of the data.
Attributes
- B
Result type of function
- f
Function Series[X, T] => B to operate on sliding window
- winSz
Window size
Left scan over the values of the Series, as in scala collections library, but with the resulting series having the same index. Note, differs from standard left scan because initial value is not retained in result.
Left scan over the values of the Series, as in scala collections library, but with the resulting series having the same index. Note, differs from standard left scan because initial value is not retained in result.
Attributes
- U
Result type of function
- f
Function taking (U, T) to U
- init
Initial value of scan
Create a new Series using the current values but with the new index. Positions of the values do not change.
Create a new Series using the current values but with the new index. Positions of the values do not change.
Attributes
- Y
Type of elements of new Index
- newIx
A new Index
Shift the sequence of values relative to the index by some offset, dropping those values which no longer associate with a key, and having those keys which no longer associate to a value instead map to NA.
Shift the sequence of values relative to the index by some offset, dropping those values which no longer associate with a key, and having those keys which no longer associate to a value instead map to NA.
Attributes
- n
Number to shift
Creates a view into original Series from one int offset until (exclusive) another offset. Data is not copied.
Creates a view into original Series from one int offset until (exclusive) another offset. Data is not copied.
Attributes
- from
Beginning offset
- until
Ending offset
Creates a view into original Series from one key up to (inclusive by default) another key. Data is not copied. Series index must be sorted.
Creates a view into original Series from one key up to (inclusive by default) another key. Data is not copied. Series index must be sorted.
Attributes
- from
Beginning offset key
- to
Ending offset key
Creates a view into original Series from one key through another key as specified in the bound argument. Data is not copied. Series index must be sorted.
Creates a view into original Series from one key through another key as specified in the bound argument. Data is not copied. Series index must be sorted.
Attributes
- rng
An IRange which computes the bound locations
Create a new Series whose key/value entries are sorted according to the values of the Series.
Create a new Series whose key/value entries are sorted according to the values of the Series.
Attributes
- ev
Implicit evidence of ordering for T
Create a new Series whose key/value entries are sorted according to the keys (index values).
Create a new Series whose key/value entries are sorted according to the keys (index values).
Attributes
Split Series into two series at position i
Split Series into two series at position i
Attributes
- i
Position at which to split Series
Split Series into two series at key x
Split Series into two series at key x
Attributes
- k
Key at which to split Series
Return a series with the current index as values and current values as index
Return a series with the current index as values and current values as index
Attributes
Extract at most the last n elements of the Series
Extract at most the last n elements of the Series
Attributes
- n
number to extract
Given int offets to take, form a new series from the keys and values found at those offsets.
Given int offets to take, form a new series from the keys and values found at those offsets.
Attributes
- locs
Array of int offsets
Converts to a single-column Frame
Converts to a single-column Frame
Attributes
- T
Type of values Vec
- X
Type of Index
- s
Series to promote
Convert Series to an indexed sequence of (key, value) pairs.
Convert Series to an indexed sequence of (key, value) pairs.
Attributes
Returns a string representation of the object.
Returns a string representation of the object.
The default representation is platform dependent.
Attributes
- Returns:
a string representation of the object.
- Definition Classes
- Any
Convert Series to a Vec, by dropping the index.
Convert Series to a Vec, by dropping the index.
Attributes
Additive inverse of Series with numeric elements
Additive inverse of Series with numeric elements
Attributes
Replaces all occurences of key
with value
, if present
Replaces all occurences of key
with value
, if present
If idx
is not present then returns the same Series
Attributes
Replaces all occurences of key
with value
, if present
Replaces all occurences of key
with value
, if present
If idx
is not present then returns the same Series
Attributes
Return Series whose keys and values are chosen via a Series[_, Boolean] where the latter contains a true value.
Return Series whose keys and values are chosen via a Series[_, Boolean] where the latter contains a true value.
Attributes
- pred
Series[_, Boolean] (or Vec[Boolean] which will implicitly convert)
Return Series whose keys and values are chosen via a Vec[Boolean] or a Series[_, Boolean] where the latter contains a true value.
Return Series whose keys and values are chosen via a Vec[Boolean] or a Series[_, Boolean] where the latter contains a true value.
Attributes
- pred
Series[_, Boolean] (or Vec[Boolean] which will implicitly convert)
Inherited methods
Integer modulus of division
Integer modulus of division
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance (divisor)
- Inherited from:
- NumericOps
Attributes
- Inherited from:
- NumericOps
Bit-wise AND
Bit-wise AND
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Logical AND
Logical AND
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Multiplication
Multiplication
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Exponentiation
Exponentiation
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance (exponent)
- Inherited from:
- NumericOps
Attributes
- Inherited from:
- NumericOps
Attributes
- Inherited from:
- NumericOps
Addition
Addition
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Attributes
- Inherited from:
- NumericOps
Subtraction
Subtraction
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Attributes
- Inherited from:
- NumericOps
Division
Division
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance (divisor)
- Inherited from:
- NumericOps
Attributes
- Inherited from:
- NumericOps
Less-than comparison operator
Less-than comparison operator
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Bit-shift left
Bit-shift left
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Less-than-or-equal-to comparison operator
Less-than-or-equal-to comparison operator
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Element-wise inequality operator
Element-wise inequality operator
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Element-wise equality operator
Element-wise equality operator
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Greater-than comparison operator
Greater-than comparison operator
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Greater-than-or-equal-to comparison operator
Greater-than-or-equal-to comparison operator
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Bit-shift right (arithmetic)
Bit-shift right (arithmetic)
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Bit-shift right (logical)
Bit-shift right (logical)
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Bit-wise EXCLUSIVE OR
Bit-wise EXCLUSIVE OR
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Dot (inner) product
Dot (inner) product
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Outer product
Outer product
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Logical EXCLUSIVE OR
Logical EXCLUSIVE OR
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Bit-wise OR
Bit-wise OR
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps
Logical OR
Logical OR
Attributes
- B
type of the other operand
- That
result type of operation
- op
implicit evidence for operation between this and other
- other
other operand instance
- Inherited from:
- NumericOps