skbio.sequence.RNA.concat#
- classmethod RNA.concat(sequences, how='strict')[source]#
Concatenate an iterable of
Sequence
objects.- Parameters:
- sequencesiterable (Sequence)
An iterable of
Sequence
objects or appropriate subclasses.- how{‘strict’, ‘inner’, ‘outer’}, optional
How to intersect the positional_metadata of the sequences. If ‘strict’: the positional_metadata must have the exact same columns; ‘inner’: an inner-join of the columns (only the shared set of columns are used); ‘outer’: an outer-join of the columns (all columns are used: missing values will be padded with NaN).
- Returns:
- Sequence
The returned sequence will be an instance of the class which called this class-method.
- Raises:
- ValueError
If how is not one of: ‘strict’, ‘inner’, or ‘outer’.
- ValueError
If how is ‘strict’ and the positional_metadata of each sequence does not have the same columns.
- TypeError
If the sequences cannot be cast as the calling class.
Notes
The sequence-wide metadata (
Sequence.metadata
) is not retained during concatenation.Sequence objects can be cast to a different type only when the new type is an ancestor or child of the original type. Casting between sibling types is not allowed, e.g.
DNA
->RNA
is not allowed, butDNA
->Sequence
orSequence
->DNA
would be.Examples
Concatenate two DNA sequences into a new DNA object:
>>> from skbio import DNA, Sequence >>> s1 = DNA("ACGT") >>> s2 = DNA("GGAA") >>> DNA.concat([s1, s2]) DNA -------------------------- Stats: length: 8 has gaps: False has degenerates: False has definites: True GC-content: 50.00% -------------------------- 0 ACGTGGAA
Concatenate DNA sequences into a Sequence object (type coercion):
>>> Sequence.concat([s1, s2]) Sequence ------------- Stats: length: 8 ------------- 0 ACGTGGAA
Positional metadata is conserved:
>>> s1 = DNA('AcgT', lowercase='one') >>> s2 = DNA('GGaA', lowercase='one', ... positional_metadata={'two': [1, 2, 3, 4]}) >>> result = DNA.concat([s1, s2], how='outer') >>> result DNA --------------------------- Positional metadata: 'one': <dtype: bool> 'two': <dtype: float64> Stats: length: 8 has gaps: False has degenerates: False has definites: True GC-content: 50.00% --------------------------- 0 ACGTGGAA >>> result.positional_metadata one two 0 False NaN 1 True NaN 2 True NaN 3 False NaN 4 False 1.0 5 False 2.0 6 True 3.0 7 False 4.0