# Copyright 2000-2003 Jeff Chang. # Copyright 2001-2008 Brad Chapman. # Copyright 2005-2015 by Peter Cock. # Copyright 2006-2009 Michiel de Hoon. # All rights reserved. # This code is part of the Biopython distribution and governed by its # license. Please see the LICENSE file that should have been included # as part of this package. """Represent a Sequence Feature holding info about a part of a sequence. This is heavily modeled after the Biocorba SeqFeature objects, and may be pretty biased towards GenBank stuff since I'm writing it for the GenBank parser output... What's here: Base class to hold a Feature ---------------------------- classes: - SeqFeature Hold information about a Reference ---------------------------------- This is an attempt to create a General class to hold Reference type information. classes: - Reference Specify locations of a feature on a Sequence -------------------------------------------- This aims to handle, in Ewan Birney's words, 'the dreaded fuzziness issue'. This has the advantages of allowing us to handle fuzzy stuff in case anyone needs it, and also be compatible with BioPerl etc and BioSQL. classes: - FeatureLocation - Specify the start and end location of a feature. - CompoundLocation - Collection of FeatureLocation objects (for joins etc). - ExactPosition - Specify the position as being exact. - WithinPosition - Specify a position occurring within some range. - BetweenPosition - Specify a position occurring between a range (OBSOLETE?). - BeforePosition - Specify the position as being found before some base. - AfterPosition - Specify the position as being found after some base. - OneOfPosition - Specify a position where the location can be multiple positions. - UnknownPosition - Represents missing information like '?' in UniProt. """ from __future__ import print_function from Bio._py3k import _is_int_or_long from Bio.Seq import MutableSeq, reverse_complement class SeqFeature(object): """Represent a Sequence Feature on an object. Attributes: - location - the location of the feature on the sequence (FeatureLocation) - type - the specified type of the feature (ie. CDS, exon, repeat...) - location_operator - a string specifying how this SeqFeature may be related to others. For example, in the example GenBank feature shown below, the location_operator would be "join". This is a proxy for feature.location.operator and only applies to compound locations. - strand - A value specifying on which strand (of a DNA sequence, for instance) the feature deals with. 1 indicates the plus strand, -1 indicates the minus strand, 0 indicates stranded but unknown (? in GFF3), while the default of None indicates that strand doesn't apply (dot in GFF3, e.g. features on proteins). Note this is a shortcut for accessing the strand property of the feature's location. - id - A string identifier for the feature. - ref - A reference to another sequence. This could be an accession number for some different sequence. Note this is a shortcut for the reference property of the feature's location. - ref_db - A different database for the reference accession number. Note this is a shortcut for the reference property of the location - qualifiers - A dictionary of qualifiers on the feature. These are analogous to the qualifiers from a GenBank feature table. The keys of the dictionary are qualifier names, the values are the qualifier values. """ def __init__(self, location=None, type='', location_operator='', strand=None, id="", qualifiers=None, sub_features=None, ref=None, ref_db=None): """Initialize a SeqFeature on a Sequence. location can either be a FeatureLocation (with strand argument also given if required), or None. e.g. With no strand, on the forward strand, and on the reverse strand: >>> from Bio.SeqFeature import SeqFeature, FeatureLocation >>> f1 = SeqFeature(FeatureLocation(5, 10), type="domain") >>> f1.strand == f1.location.strand == None True >>> f2 = SeqFeature(FeatureLocation(7, 110, strand=1), type="CDS") >>> f2.strand == f2.location.strand == +1 True >>> f3 = SeqFeature(FeatureLocation(9, 108, strand=-1), type="CDS") >>> f3.strand == f3.location.strand == -1 True An invalid strand will trigger an exception: >>> f4 = SeqFeature(FeatureLocation(50, 60), strand=2) Traceback (most recent call last): ... ValueError: Strand should be +1, -1, 0 or None, not 2 Similarly if set via the FeatureLocation directly: >>> loc4 = FeatureLocation(50, 60, strand=2) Traceback (most recent call last): ... ValueError: Strand should be +1, -1, 0 or None, not 2 For exact start/end positions, an integer can be used (as shown above) as shorthand for the ExactPosition object. For non-exact locations, the FeatureLocation must be specified via the appropriate position objects. Note that the strand, ref and ref_db arguments to the SeqFeature are now obsolete and will be deprecated in a future release (which will give warning messages) and later removed. Set them via the location object instead. Note that location_operator and sub_features arguments can no longer be used, instead do this via the CompoundLocation object. """ if location is not None and not isinstance(location, FeatureLocation) \ and not isinstance(location, CompoundLocation): raise TypeError( "FeatureLocation, CompoundLocation (or None) required for the location") self.location = location self.type = type if location_operator: # TODO - Deprecation warning self.location_operator = location_operator if strand is not None: # TODO - Deprecation warning self.strand = strand self.id = id if qualifiers is None: qualifiers = {} self.qualifiers = qualifiers if sub_features is not None: raise TypeError("Rather than sub_features, use a CompoundFeatureLocation") if ref is not None: # TODO - Deprecation warning self.ref = ref if ref_db is not None: # TODO - Deprecation warning self.ref_db = ref_db def _get_strand(self): return self.location.strand def _set_strand(self, value): try: self.location.strand = value except AttributeError: if self.location is None: if value is not None: raise ValueError("Can't set strand without a location.") else: raise strand = property(fget=_get_strand, fset=_set_strand, doc="""Feature's strand This is a shortcut for feature.location.strand """) def _get_ref(self): try: return self.location.ref except AttributeError: return None def _set_ref(self, value): try: self.location.ref = value except AttributeError: if self.location is None: if value is not None: raise ValueError("Can't set ref without a location.") else: raise ref = property(fget=_get_ref, fset=_set_ref, doc="""Feature location reference (e.g. accession). This is a shortcut for feature.location.ref """) def _get_ref_db(self): try: return self.location.ref_db except AttributeError: return None def _set_ref_db(self, value): self.location.ref_db = value ref_db = property(fget=_get_ref_db, fset=_set_ref_db, doc="""Feature location reference's database. This is a shortcut for feature.location.ref_db """) def _get_location_operator(self): try: return self.location.operator except AttributeError: return None def _set_location_operator(self, value): if value: if isinstance(self.location, CompoundLocation): self.location.operator = value elif self.location is None: raise ValueError( "Location is None so can't set its operator (to %r)" % value) else: raise ValueError( "Only CompoundLocation gets an operator (%r)" % value) location_operator = property(fget=_get_location_operator, fset=_set_location_operator, doc="Location operator for compound locations (e.g. join).") def __repr__(self): """A string representation of the record for debugging.""" answer = "%s(%s" % (self.__class__.__name__, repr(self.location)) if self.type: answer += ", type=%s" % repr(self.type) if self.location_operator: answer += ", location_operator=%s" % repr(self.location_operator) if self.id and self.id != "": answer += ", id=%s" % repr(self.id) if self.ref: answer += ", ref=%s" % repr(self.ref) if self.ref_db: answer += ", ref_db=%s" % repr(self.ref_db) answer += ")" return answer def __str__(self): """A readable summary of the feature intended to be printed to screen. """ out = "type: %s\n" % self.type out += "location: %s\n" % self.location if self.id and self.id != "": out += "id: %s\n" % self.id out += "qualifiers:\n" for qual_key in sorted(self.qualifiers): out += " Key: %s, Value: %s\n" % (qual_key, self.qualifiers[qual_key]) return out def _shift(self, offset): """Returns a copy of the feature with its location shifted (PRIVATE). The annotation qaulifiers are copied.""" return SeqFeature(location=self.location._shift(offset), type=self.type, location_operator=self.location_operator, id=self.id, qualifiers=dict(self.qualifiers.items())) def _flip(self, length): """Returns a copy of the feature with its location flipped (PRIVATE). The argument length gives the length of the parent sequence. For example a location 0..20 (+1 strand) with parent length 30 becomes after flipping 10..30 (-1 strand). Strandless (None) or unknown strand (0) remain like that - just their end points are changed. The annotation qaulifiers are copied. """ return SeqFeature(location=self.location._flip(length), type=self.type, location_operator=self.location_operator, id=self.id, qualifiers=dict(self.qualifiers.items())) def extract(self, parent_sequence): """Extract feature sequence from the supplied parent sequence. The parent_sequence can be a Seq like object or a string, and will generally return an object of the same type. The exception to this is a MutableSeq as the parent sequence will return a Seq object. This should cope with complex locations including complements, joins and fuzzy positions. Even mixed strand features should work! This also covers features on protein sequences (e.g. domains), although here reverse strand features are not permitted. >>> from Bio.Seq import Seq >>> from Bio.Alphabet import generic_protein >>> from Bio.SeqFeature import SeqFeature, FeatureLocation >>> seq = Seq("MKQHKAMIVALIVICITAVVAAL", generic_protein) >>> f = SeqFeature(FeatureLocation(8, 15), type="domain") >>> f.extract(seq) Seq('VALIVIC', ProteinAlphabet()) If the FeatureLocation is None, e.g. when parsing invalid locus locations in the GenBank parser, extract() will raise a ValueError. >>> from Bio.Seq import Seq >>> from Bio.SeqFeature import SeqFeature >>> seq = Seq("MKQHKAMIVALIVICITAVVAAL", generic_protein) >>> f = SeqFeature(None, type="domain") >>> f.extract(seq) Traceback (most recent call last): ... ValueError: The feature's .location is None. Check the sequence file for a valid location. Note - currently only compound features of type "join" are supported. """ if self.location is None: raise ValueError("The feature's .location is None. Check the " "sequence file for a valid location.") return self.location.extract(parent_sequence) # Python 3: def __bool__(self): """Boolean value of an instance of this class (True). This behaviour is for backwards compatibility, since until the __len__ method was added, a SeqFeature always evaluated as True. Note that in comparison, Seq objects, strings, lists, etc, will all evaluate to False if they have length zero. WARNING: The SeqFeature may in future evaluate to False when its length is zero (in order to better match normal python behaviour)! """ return True # Python 2: __nonzero__ = __bool__ def __len__(self): """Returns the length of the region described by a feature. >>> from Bio.Seq import Seq >>> from Bio.Alphabet import generic_protein >>> from Bio.SeqFeature import SeqFeature, FeatureLocation >>> seq = Seq("MKQHKAMIVALIVICITAVVAAL", generic_protein) >>> f = SeqFeature(FeatureLocation(8, 15), type="domain") >>> len(f) 7 >>> f.extract(seq) Seq('VALIVIC', ProteinAlphabet()) >>> len(f.extract(seq)) 7 This is a proxy for taking the length of the feature's location: >>> len(f.location) 7 For simple features this is the same as the region spanned (end position minus start position using Pythonic counting). However, for a compound location (e.g. a CDS as the join of several exons) the gaps are not counted (e.g. introns). This ensures that len(f) matches len(f.extract(parent_seq)), and also makes sure things work properly with features wrapping the origin etc. """ return len(self.location) def __iter__(self): """Iterate over the parent positions within the feature. The iteration order is strand aware, and can be thought of as moving along the feature using the parent sequence coordinates: >>> from Bio.SeqFeature import SeqFeature, FeatureLocation >>> f = SeqFeature(FeatureLocation(5, 10), type="domain", strand=-1) >>> len(f) 5 >>> for i in f: print(i) 9 8 7 6 5 >>> list(f) [9, 8, 7, 6, 5] This is a proxy for iterating over the location, >>> list(f.location) [9, 8, 7, 6, 5] """ return iter(self.location) def __contains__(self, value): """Check if an integer position is within the feature. >>> from Bio.SeqFeature import SeqFeature, FeatureLocation >>> f = SeqFeature(FeatureLocation(5, 10), type="domain", strand=-1) >>> len(f) 5 >>> [i for i in range(15) if i in f] [5, 6, 7, 8, 9] For example, to see which features include a SNP position, you could use this: >>> from Bio import SeqIO >>> record = SeqIO.read("GenBank/NC_000932.gb", "gb") >>> for f in record.features: ... if 1750 in f: ... print("%s %s" % (f.type, f.location)) source [0:154478](+) gene [1716:4347](-) tRNA join{[4310:4347](-), [1716:1751](-)} Note that for a feature defined as a join of several subfeatures (e.g. the union of several exons) the gaps are not checked (e.g. introns). In this example, the tRNA location is defined in the GenBank file as complement(join(1717..1751,4311..4347)), so that position 1760 falls in the gap: >>> for f in record.features: ... if 1760 in f: ... print("%s %s" % (f.type, f.location)) source [0:154478](+) gene [1716:4347](-) Note that additional care may be required with fuzzy locations, for example just before a BeforePosition: >>> from Bio.SeqFeature import SeqFeature, FeatureLocation >>> from Bio.SeqFeature import BeforePosition >>> f = SeqFeature(FeatureLocation(BeforePosition(3), 8), type="domain") >>> len(f) 5 >>> [i for i in range(10) if i in f] [3, 4, 5, 6, 7] Note that is is a proxy for testing membership on the location. >>> [i for i in range(10) if i in f.location] [3, 4, 5, 6, 7] """ return value in self.location # --- References # TODO -- Will this hold PubMed and Medline information decently? class Reference(object): """Represent a Generic Reference object. Attributes: o location - A list of Location objects specifying regions of the sequence that the references correspond to. If no locations are specified, the entire sequence is assumed. o authors - A big old string, or a list split by author, of authors for the reference. o title - The title of the reference. o journal - Journal the reference was published in. o medline_id - A medline reference for the article. o pubmed_id - A pubmed reference for the article. o comment - A place to stick any comments about the reference. """ def __init__(self): self.location = [] self.authors = '' self.consrtm = '' self.title = '' self.journal = '' self.medline_id = '' self.pubmed_id = '' self.comment = '' def __str__(self): """Output an informative string for debugging. """ out = "" for single_location in self.location: out += "location: %s\n" % single_location out += "authors: %s\n" % self.authors if self.consrtm: out += "consrtm: %s\n" % self.consrtm out += "title: %s\n" % self.title out += "journal: %s\n" % self.journal out += "medline id: %s\n" % self.medline_id out += "pubmed id: %s\n" % self.pubmed_id out += "comment: %s\n" % self.comment return out def __repr__(self): # TODO - Update this is __init__ later accpets values return "%s(title=%s, ...)" % (self.__class__.__name__, repr(self.title)) def __eq__(self, other): """Check if two Reference objects should be considered equal Note that the location is not compared, as __eq__ for the FeatureLocation class is not defined. """ return self.authors == other.authors and \ self.consrtm == other.consrtm and \ self.title == other.title and \ self.journal == other.journal and \ self.medline_id == other.medline_id and \ self.pubmed_id == other.pubmed_id and \ self.comment == other.comment # --- Handling feature locations class FeatureLocation(object): """Specify the location of a feature along a sequence. The FeatureLocation is used for simple continuous features, which can be described as running from a start position to and end position (optionally with a strand and reference information). More complex locations made up from several non-continuous parts (e.g. a coding sequence made up of several exons) are described using a SeqFeature with a CompoundLocation. Note that the start and end location numbering follow Python's scheme, thus a GenBank entry of 123..150 (one based counting) becomes a location of [122:150] (zero based counting). >>> from Bio.SeqFeature import FeatureLocation >>> f = FeatureLocation(122, 150) >>> print(f) [122:150] >>> print(f.start) 122 >>> print(f.end) 150 >>> print(f.strand) None Note the strand defaults to None. If you are working with nucleotide sequences you'd want to be explicit if it is the forward strand: >>> from Bio.SeqFeature import FeatureLocation >>> f = FeatureLocation(122, 150, strand=+1) >>> print(f) [122:150](+) >>> print(f.strand) 1 Note that for a parent sequence of length n, the FeatureLocation start and end must satisfy the inequality 0 <= start <= end <= n. This means even for features on the reverse strand of a nucleotide sequence, we expect the 'start' coordinate to be less than the 'end'. >>> from Bio.SeqFeature import FeatureLocation >>> r = FeatureLocation(122, 150, strand=-1) >>> print(r) [122:150](-) >>> print(r.start) 122 >>> print(r.end) 150 >>> print(r.strand) -1 i.e. Rather than thinking of the 'start' and 'end' biologically in a strand aware manor, think of them as the 'left most' or 'minimum' boundary, and the 'right most' or 'maximum' boundary of the region being described. This is particularly important with compound locations describing non-continuous regions. In the example above we have used standard exact positions, but there are also specialised position objects used to represent fuzzy positions as well, for example a GenBank location like complement(<123..150) would use a BeforePosition object for the start. """ def __init__(self, start, end, strand=None, ref=None, ref_db=None): """Specify the start, end, strand etc of a sequence feature. start and end arguments specify the values where the feature begins and ends. These can either by any of the ``*Position`` objects that inherit from AbstractPosition, or can just be integers specifying the position. In the case of integers, the values are assumed to be exact and are converted in ExactPosition arguments. This is meant to make it easy to deal with non-fuzzy ends. i.e. Short form: >>> from Bio.SeqFeature import FeatureLocation >>> loc = FeatureLocation(5, 10, strand=-1) >>> print(loc) [5:10](-) Explicit form: >>> from Bio.SeqFeature import FeatureLocation, ExactPosition >>> loc = FeatureLocation(ExactPosition(5), ExactPosition(10), strand=-1) >>> print(loc) [5:10](-) Other fuzzy positions are used similarly, >>> from Bio.SeqFeature import FeatureLocation >>> from Bio.SeqFeature import BeforePosition, AfterPosition >>> loc2 = FeatureLocation(BeforePosition(5), AfterPosition(10), strand=-1) >>> print(loc2) [<5:>10](-) For nucleotide features you will also want to specify the strand, use 1 for the forward (plus) strand, -1 for the reverse (negative) strand, 0 for stranded but strand unknown (? in GFF3), or None for when the strand does not apply (dot in GFF3), e.g. features on proteins. >>> loc = FeatureLocation(5, 10, strand=+1) >>> print(loc) [5:10](+) >>> print(loc.strand) 1 Normally feature locations are given relative to the parent sequence you are working with, but an explicit accession can be given with the optional ref and db_ref strings: >>> loc = FeatureLocation(105172, 108462, ref="AL391218.9", strand=1) >>> print(loc) AL391218.9[105172:108462](+) >>> print(loc.ref) AL391218.9 """ # TODO - Check 0 <= start <= end (<= length of reference) if isinstance(start, AbstractPosition): self._start = start elif _is_int_or_long(start): self._start = ExactPosition(start) else: raise TypeError("start=%r %s" % (start, type(start))) if isinstance(end, AbstractPosition): self._end = end elif _is_int_or_long(end): self._end = ExactPosition(end) else: raise TypeError("end=%r %s" % (end, type(end))) self.strand = strand self.ref = ref self.ref_db = ref_db def _get_strand(self): return self._strand def _set_strand(self, value): if value not in [+1, -1, 0, None]: raise ValueError("Strand should be +1, -1, 0 or None, not %r" % value) self._strand = value strand = property(fget=_get_strand, fset=_set_strand, doc="Strand of the location (+1, -1, 0 or None).") def __str__(self): """Returns a representation of the location (with python counting). For the simple case this uses the python splicing syntax, [122:150] (zero based counting) which GenBank would call 123..150 (one based counting). """ answer = "[%s:%s]" % (self._start, self._end) if self.ref and self.ref_db: answer = "%s:%s%s" % (self.ref_db, self.ref, answer) elif self.ref: answer = self.ref + answer # Is ref_db without ref meaningful? if self.strand is None: return answer elif self.strand == +1: return answer + "(+)" elif self.strand == -1: return answer + "(-)" else: # strand = 0, stranded but strand unknown, ? in GFF3 return answer + "(?)" def __repr__(self): """A string representation of the location for debugging.""" optional = "" if self.strand is not None: optional += ", strand=%r" % self.strand if self.ref is not None: optional += ", ref=%r" % self.ref if self.ref_db is not None: optional += ", ref_db=%r" % self.ref_db return "%s(%r, %r%s)" \ % (self.__class__.__name__, self.start, self.end, optional) def __add__(self, other): """Combine location with another feature location, or shift it. You can add two feature locations to make a join CompoundLocation: >>> from Bio.SeqFeature import FeatureLocation >>> f1 = FeatureLocation(5, 10) >>> f2 = FeatureLocation(20, 30) >>> combined = f1 + f2 >>> print(combined) join{[5:10], [20:30]} This is thus equivalent to: >>> from Bio.SeqFeature import CompoundLocation >>> join = CompoundLocation([f1, f2]) >>> print(join) join{[5:10], [20:30]} You can also use sum(...) in this way: >>> join = sum([f1, f2]) >>> print(join) join{[5:10], [20:30]} Furthermore, you can combine a FeatureLocation with a CompoundLocation in this way. Separately, adding an integer will give a new FeatureLocation with its start and end offset by that amount. For example: >>> print(f1) [5:10] >>> print(f1 + 100) [105:110] >>> print(200 + f1) [205:210] This can be useful when editing annotation. """ if isinstance(other, FeatureLocation): return CompoundLocation([self, other]) elif isinstance(other, int): return self._shift(other) else: # This will allow CompoundLocation's __radd__ to be called: return NotImplemented def __radd__(self, other): if isinstance(other, int): return self._shift(other) else: return NotImplemented def __nonzero__(self): """Returns True regardless of the length of the feature. This behaviour is for backwards compatibility, since until the __len__ method was added, a FeatureLocation always evaluated as True. Note that in comparison, Seq objects, strings, lists, etc, will all evaluate to False if they have length zero. WARNING: The FeatureLocation may in future evaluate to False when its length is zero (in order to better match normal python behaviour)! """ return True def __len__(self): """Returns the length of the region described by the FeatureLocation. Note that extra care may be needed for fuzzy locations, e.g. >>> from Bio.SeqFeature import FeatureLocation >>> from Bio.SeqFeature import BeforePosition, AfterPosition >>> loc = FeatureLocation(BeforePosition(5), AfterPosition(10)) >>> len(loc) 5 """ return int(self._end) - int(self._start) def __contains__(self, value): """Check if an integer position is within the FeatureLocation. Note that extra care may be needed for fuzzy locations, e.g. >>> from Bio.SeqFeature import FeatureLocation >>> from Bio.SeqFeature import BeforePosition, AfterPosition >>> loc = FeatureLocation(BeforePosition(5), AfterPosition(10)) >>> len(loc) 5 >>> [i for i in range(15) if i in loc] [5, 6, 7, 8, 9] """ if not isinstance(value, int): raise ValueError("Currently we only support checking for integer " "positions being within a FeatureLocation.") if value < self._start or value >= self._end: return False else: return True def __iter__(self): """Iterate over the parent positions within the FeatureLocation. >>> from Bio.SeqFeature import FeatureLocation >>> from Bio.SeqFeature import BeforePosition, AfterPosition >>> loc = FeatureLocation(BeforePosition(5), AfterPosition(10)) >>> len(loc) 5 >>> for i in loc: print(i) 5 6 7 8 9 >>> list(loc) [5, 6, 7, 8, 9] >>> [i for i in range(15) if i in loc] [5, 6, 7, 8, 9] Note this is strand aware: >>> loc = FeatureLocation(BeforePosition(5), AfterPosition(10), strand = -1) >>> list(loc) [9, 8, 7, 6, 5] """ if self.strand == -1: for i in range(self._end - 1, self._start - 1, -1): yield i else: for i in range(self._start, self._end): yield i def _shift(self, offset): """Returns a copy of the location shifted by the offset (PRIVATE).""" # TODO - What if offset is a fuzzy position? if self.ref or self.ref_db: # TODO - Return self? raise ValueError("Feature references another sequence.") return FeatureLocation(start=self._start._shift(offset), end=self._end._shift(offset), strand=self.strand) def _flip(self, length): """Returns a copy of the location after the parent is reversed (PRIVATE).""" if self.ref or self.ref_db: # TODO - Return self? raise ValueError("Feature references another sequence.") # Note this will flip the start and end too! if self.strand == +1: flip_strand = -1 elif self.strand == -1: flip_strand = +1 else: # 0 or None flip_strand = self.strand return FeatureLocation(start=self._end._flip(length), end=self._start._flip(length), strand=flip_strand) @property def parts(self): """Read only list of parts (always one, the Feature Location). This is a convenience property allowing you to write code handling both simple FeatureLocation objects (with one part) and more complex CompoundLocation objects (with multiple parts) interchangeably. """ return [self] @property def start(self): """Start location - left most (minimum) value, regardless of strand. Read only, returns an integer like position object, possibly a fuzzy position. """ return self._start @property def end(self): """End location - right most (maximum) value, regardless of strand. Read only, returns an integer like position object, possibly a fuzzy position. """ return self._end @property def nofuzzy_start(self): """Start position (integer, approximated if fuzzy, read only) (OBSOLETE). This is now an alias for int(feature.start), which should be used in preference -- unless you are trying to support old versions of Biopython. """ try: return int(self._start) except TypeError: if isinstance(self._start, UnknownPosition): return None raise @property def nofuzzy_end(self): """End position (integer, approximated if fuzzy, read only) (OBSOLETE). This is now an alias for int(feature.end), which should be used in preference -- unless you are trying to support old versions of Biopython. """ try: return int(self._end) except TypeError: if isinstance(self._end, UnknownPosition): return None raise def extract(self, parent_sequence): """Extract feature sequence from the supplied parent sequence.""" if self.ref or self.ref_db: # TODO - Take a dictionary as an optional argument? raise ValueError("Feature references another sequence.") if isinstance(parent_sequence, MutableSeq): # This avoids complications with reverse complements # (the MutableSeq reverse complement acts in situ) parent_sequence = parent_sequence.toseq() f_seq = parent_sequence[self.nofuzzy_start:self.nofuzzy_end] if self.strand == -1: try: f_seq = f_seq.reverse_complement() except AttributeError: assert isinstance(f_seq, str) f_seq = reverse_complement(f_seq) return f_seq class CompoundLocation(object): """For handling joins etc where a feature location has several parts.""" def __init__(self, parts, operator="join"): """Create a compound location with several parts. >>> from Bio.SeqFeature import FeatureLocation, CompoundLocation >>> f1 = FeatureLocation(10, 40, strand=+1) >>> f2 = FeatureLocation(50, 59, strand=+1) >>> f = CompoundLocation([f1, f2]) >>> len(f) == len(f1) + len(f2) == 39 == len(list(f)) True >>> print(f.operator) join >>> 5 in f False >>> 15 in f True >>> f.strand 1 Notice that the strand of the compound location is computed automatically - in the case of mixed strands on the sub-locations the overall strand is set to None. >>> f = CompoundLocation([FeatureLocation(3, 6, strand=+1), ... FeatureLocation(10, 13, strand=-1)]) >>> print(f.strand) None >>> len(f) 6 >>> list(f) [3, 4, 5, 12, 11, 10] The example above doing list(f) iterates over the coordinates within the feature. This allows you to use max and min on the location, to find the range covered: >>> min(f) 3 >>> max(f) 12 More generally, you can use the compound location's start and end which give the full range covered, 0 <= start <= end <= full sequence length. >>> f.start == min(f) True >>> f.end == max(f) + 1 True This is consistent with the behaviour of the simple FeatureLocation for a single region, where again the 'start' and 'end' do not necessarily give the biological start and end, but rather the 'minimal' and 'maximal' coordinate boundaries. Note that adding locations provides a more intuitive method of construction: >>> f = FeatureLocation(3, 6, strand=+1) + FeatureLocation(10, 13, strand=-1) >>> len(f) 6 >>> list(f) [3, 4, 5, 12, 11, 10] """ self.operator = operator self.parts = list(parts) for loc in self.parts: if not isinstance(loc, FeatureLocation): raise ValueError("CompoundLocation should be given a list of " "FeatureLocation objects, not %s" % loc.__class__) if len(parts) < 2: raise ValueError( "CompoundLocation should have at least 2 parts, not %r" % parts) def __str__(self): """Returns a representation of the location (with python counting).""" return "%s{%s}" % (self.operator, ", ".join(str(loc) for loc in self.parts)) def __repr__(self): """String representation of the location for debugging.""" return "%s(%r, %r)" % (self.__class__.__name__, self.parts, self.operator) def _get_strand(self): # Historically a join on the reverse strand has been represented # in Biopython with both the parent SeqFeature and its children # (the exons for a CDS) all given a strand of -1. Likewise, for # a join feature on the forward strand they all have strand +1. # However, we must also consider evil mixed strand examples like # this, join(complement(69611..69724),139856..140087,140625..140650) if len(set(loc.strand for loc in self.parts)) == 1: return self.parts[0].strand else: return None # i.e. mixed strands def _set_strand(self, value): # Should this be allowed/encouraged? for loc in self.parts: loc.strand = value strand = property(fget=_get_strand, fset=_set_strand, doc="""Overall strand of the compound location. If all the parts have the same strand, that is returned. Otherwise for mixed strands, this returns None. >>> from Bio.SeqFeature import FeatureLocation, CompoundLocation >>> f1 = FeatureLocation(15, 17, strand=1) >>> f2 = FeatureLocation(20, 30, strand=-1) >>> f = f1 + f2 >>> f1.strand 1 >>> f2.strand -1 >>> f.strand >>> f.strand is None True If you set the strand of a CompoundLocation, this is applied to all the parts - use with caution: >>> f.strand = 1 >>> f1.strand 1 >>> f2.strand 1 >>> f.strand 1 """) def __add__(self, other): """Combine locations, or shift the location by an integer offset. >>> from Bio.SeqFeature import FeatureLocation, CompoundLocation >>> f1 = FeatureLocation(15, 17) + FeatureLocation(20, 30) >>> print(f1) join{[15:17], [20:30]} You can add another FeatureLocation: >>> print(f1 + FeatureLocation(40, 50)) join{[15:17], [20:30], [40:50]} >>> print(FeatureLocation(5, 10) + f1) join{[5:10], [15:17], [20:30]} You can also add another CompoundLocation: >>> f2 = FeatureLocation(40, 50) + FeatureLocation(60, 70) >>> print(f2) join{[40:50], [60:70]} >>> print(f1 + f2) join{[15:17], [20:30], [40:50], [60:70]} Also, as with the FeatureLocation, adding an integer shifts the location's co-ordinates by that offset: >>> print(f1 + 100) join{[115:117], [120:130]} >>> print(200 + f1) join{[215:217], [220:230]} >>> print(f1 + (-5)) join{[10:12], [15:25]} """ if isinstance(other, FeatureLocation): return CompoundLocation(self.parts + [other], self.operator) elif isinstance(other, CompoundLocation): if self.operator != other.operator: # Handle join+order -> order as a special case? raise ValueError("Mixed operators %s and %s" % (self.operator, other.operator)) return CompoundLocation(self.parts + other.parts, self.operator) elif isinstance(other, int): return self._shift(other) else: raise NotImplementedError def __radd__(self, other): """Combine locations.""" if isinstance(other, FeatureLocation): return CompoundLocation([other] + self.parts, self.operator) elif isinstance(other, int): return self._shift(other) else: raise NotImplementedError def __contains__(self, value): """Check if an integer position is within the location.""" for loc in self.parts: if value in loc: return True return False def __nonzero__(self): """Returns True regardless of the length of the feature. This behaviour is for backwards compatibility, since until the __len__ method was added, a FeatureLocation always evaluated as True. Note that in comparison, Seq objects, strings, lists, etc, will all evaluate to False if they have length zero. WARNING: The FeatureLocation may in future evaluate to False when its length is zero (in order to better match normal python behaviour)! """ return True def __len__(self): return sum(len(loc) for loc in self.parts) def __iter__(self): for loc in self.parts: for pos in loc: yield pos def _shift(self, offset): """Returns a copy of the location shifted by the offset (PRIVATE).""" return CompoundLocation([loc._shift(offset) for loc in self.parts], self.operator) def _flip(self, length): """Returns a copy of the location after the parent is reversed (PRIVATE). Note that the order of the parts is NOT reversed too. Consider a CDS on the forward strand with exons small, medium and large (in length). Once we change the frame of reference to the reverse complement strand, the start codon is still part of the small exon, and the stop codon still part of the large exon - so the part order remains the same! Here is an artificial example, were the features map to the two upper case regions and the lower case runs of n are not used: >>> from Bio.Seq import Seq >>> from Bio.SeqFeature import FeatureLocation >>> dna = Seq("nnnnnAGCATCCTGCTGTACnnnnnnnnGAGAMTGCCATGCCCCTGGAGTGAnnnnn") >>> small = FeatureLocation(5, 20, strand=1) >>> large = FeatureLocation(28, 52, strand=1) >>> location = small + large >>> print(small) [5:20](+) >>> print(large) [28:52](+) >>> print(location) join{[5:20](+), [28:52](+)} >>> for part in location.parts: ... print(len(part)) ... 15 24 As you can see, this is a silly example where each "exon" is a word: >>> print(small.extract(dna).translate()) SILLY >>> print(large.extract(dna).translate()) EXAMPLE* >>> print(location.extract(dna).translate()) SILLYEXAMPLE* >>> for part in location.parts: ... print(part.extract(dna).translate()) ... SILLY EXAMPLE* Now, let's look at this from the reverse strand frame of reference: >>> flipped_dna = dna.reverse_complement() >>> flipped_location = location._flip(len(dna)) >>> print(flipped_location.extract(flipped_dna).translate()) SILLYEXAMPLE* >>> for part in flipped_location.parts: ... print(part.extract(flipped_dna).translate()) ... SILLY EXAMPLE* The key point here is the first part of the CompoundFeature is still the small exon, while the second part is still the large exon: >>> for part in flipped_location.parts: ... print(len(part)) ... 15 24 >>> print(flipped_location) join{[37:52](-), [5:29](-)} Notice the parts are not reversed. However, there was a bug here in older versions of Biopython which would have given join{[5:29](-), [37:52](-)} and the translation would have wrongly been "EXAMPLE*SILLY" instead. """ return CompoundLocation([loc._flip(length) for loc in self.parts], self.operator) @property def start(self): """Start location - left most (minimum) value, regardless of strand. Read only, returns an integer like position object, possibly a fuzzy position. For the special case of a CompoundLocation wrapping the origin of a circular genome, this will return zero. """ return min(loc.start for loc in self.parts) @property def end(self): """End location - right most (maximum) value, regardless of strand. Read only, returns an integer like position object, possibly a fuzzy position. For the special case of a CompoundLocation wrapping the origin of a circular genome this will match the genome length (minus one given how Python counts from zero). """ return max(loc.end for loc in self.parts) @property def nofuzzy_start(self): """Start position (integer, approximated if fuzzy, read only) (OBSOLETE). This is an alias for int(feature.start), which should be used in preference -- unless you are trying to support old versions of Biopython. """ try: return int(self.start) except TypeError: if isinstance(self.start, UnknownPosition): return None raise @property def nofuzzy_end(self): """End position (integer, approximated if fuzzy, read only) (OBSOLETE). This is an alias for int(feature.end), which should be used in preference -- unless you are trying to support old versions of Biopython. """ try: return int(self.end) except TypeError: if isinstance(self.end, UnknownPosition): return None raise @property def ref(self): """CompoundLocation's don't have a ref (dummy method for API compatibility).""" return None @property def ref_db(self): """CompoundLocation's don't have a ref_db (dummy method for API compatibility).""" return None def extract(self, parent_sequence): """Extract feature sequence from the supplied parent sequence.""" # This copes with mixed strand features & all on reverse: parts = [loc.extract(parent_sequence) for loc in self.parts] # We use addition rather than a join to avoid alphabet issues: f_seq = parts[0] for part in parts[1:]: f_seq += part return f_seq class AbstractPosition(object): """Abstract base class representing a position.""" def __repr__(self): """String representation of the location for debugging.""" return "%s(...)" % (self.__class__.__name__) class ExactPosition(int, AbstractPosition): """Specify the specific position of a boundary. o position - The position of the boundary. o extension - An optional argument which must be zero since we don't have an extension. The argument is provided so that the same number of arguments can be passed to all position types. In this case, there is no fuzziness associated with the position. >>> p = ExactPosition(5) >>> p ExactPosition(5) >>> print(p) 5 >>> isinstance(p, AbstractPosition) True >>> isinstance(p, int) True Integer comparisons and operations should work as expected: >>> p == 5 True >>> p < 6 True >>> p <= 5 True >>> p + 10 15 """ def __new__(cls, position, extension=0): if extension != 0: raise AttributeError("Non-zero extension %s for exact position." % extension) return int.__new__(cls, position) def __repr__(self): """String representation of the ExactPosition location for debugging.""" return "%s(%i)" % (self.__class__.__name__, int(self)) @property def position(self): """Legacy attribute to get position as integer (OBSOLETE).""" return int(self) @property def extension(self): """Legacy attribute to get extension (zero) as integer (OBSOLETE).""" return 0 def _shift(self, offset): # By default preserve any subclass return self.__class__(int(self) + offset) def _flip(self, length): # By default perserve any subclass return self.__class__(length - int(self)) class UncertainPosition(ExactPosition): """Specify a specific position which is uncertain. This is used in UniProt, e.g. ?222 for uncertain position 222, or in the XML format explicitly marked as uncertain. Does not apply to GenBank/EMBL. """ pass class UnknownPosition(AbstractPosition): """Specify a specific position which is unknown (has no position). This is used in UniProt, e.g. ? or in the XML as unknown. """ def __repr__(self): """String representation of the UnknownPosition location for debugging.""" return "%s()" % self.__class__.__name__ def __hash__(self): return hash(None) @property def position(self): """Legacy attribute to get position (None) (OBSOLETE).""" return None @property def extension(self): """Legacy attribute to get extension (zero) as integer (OBSOLETE).""" return 0 def _shift(self, offset): return self def _flip(self, length): return self class WithinPosition(int, AbstractPosition): """Specify the position of a boundary within some coordinates. Arguments: o position - The default integer position o left - The start (left) position of the boundary o right - The end (right) position of the boundary This allows dealing with a position like ((1.4)..100). This indicates that the start of the sequence is somewhere between 1 and 4. Since this is a start coordinate, it should acts like it is at position 1 (or in Python counting, 0). >>> p = WithinPosition(10, 10, 13) >>> p WithinPosition(10, left=10, right=13) >>> print(p) (10.13) >>> int(p) 10 Basic integer comparisons and operations should work as though this were a plain integer: >>> p == 10 True >>> p in [9, 10, 11] True >>> p < 11 True >>> p + 10 20 >>> isinstance(p, WithinPosition) True >>> isinstance(p, AbstractPosition) True >>> isinstance(p, int) True Note this also applies for comparison to other position objects, where again the integer behaviour is used: >>> p == 10 True >>> p == ExactPosition(10) True >>> p == BeforePosition(10) True >>> p == AfterPosition(10) True If this were an end point, you would want the position to be 13: >>> p2 = WithinPosition(13, 10, 13) >>> p2 WithinPosition(13, left=10, right=13) >>> print(p2) (10.13) >>> int(p2) 13 >>> p2 == 13 True >>> p2 == ExactPosition(13) True The old legacy properties of position and extension give the starting/lower/left position as an integer, and the distance to the ending/higher/right position as an integer. Note that the position object will act like either the left or the right end-point depending on how it was created: >>> p.position == p2.position == 10 True >>> p.extension == p2.extension == 3 True >>> int(p) == int(p2) False >>> p == 10 True >>> p2 == 13 True """ def __new__(cls, position, left, right): assert position == left or position == right, \ "WithinPosition: %r should match left %r or right %r" \ % (position, left, right) obj = int.__new__(cls, position) obj._left = left obj._right = right return obj def __repr__(self): """String representation of the WithinPosition location for debugging.""" return "%s(%i, left=%i, right=%i)" \ % (self.__class__.__name__, int(self), self._left, self._right) def __str__(self): return "(%s.%s)" % (self._left, self._right) @property def position(self): """Legacy attribute to get (left) position as integer (OBSOLETE).""" return self._left @property def extension(self): """Legacy attribute to get extension (from left to right) as an integer (OBSOLETE).""" return self._right - self._left def _shift(self, offset): return self.__class__(int(self) + offset, self._left + offset, self._right + offset) def _flip(self, length): return self.__class__(length - int(self), length - self._right, length - self._left) class BetweenPosition(int, AbstractPosition): """Specify the position of a boundary between two coordinates (OBSOLETE?). Arguments: o position - The default integer position o left - The start (left) position of the boundary o right - The end (right) position of the boundary This allows dealing with a position like 123^456. This indicates that the start of the sequence is somewhere between 123 and 456. It is up to the parser to set the position argument to either boundary point (depending on if this is being used as a start or end of the feature). For example as a feature end: >>> p = BetweenPosition(456, 123, 456) >>> p BetweenPosition(456, left=123, right=456) >>> print(p) (123^456) >>> int(p) 456 Integer equality and comparison use the given position, >>> p == 456 True >>> p in [455, 456, 457] True >>> p > 300 True The old legacy properties of position and extension give the starting/lower/left position as an integer, and the distance to the ending/higher/right position as an integer. Note that the position object will act like either the left or the right end-point depending on how it was created: >>> p2 = BetweenPosition(123, left=123, right=456) >>> p.position == p2.position == 123 True >>> p.extension 333 >>> p2.extension 333 >>> p.extension == p2.extension == 333 True >>> int(p) == int(p2) False >>> p == 456 True >>> p2 == 123 True Note this potentially surprising behaviour: >>> BetweenPosition(123, left=123, right=456) == ExactPosition(123) True >>> BetweenPosition(123, left=123, right=456) == BeforePosition(123) True >>> BetweenPosition(123, left=123, right=456) == AfterPosition(123) True i.e. For equality (and sorting) the position objects behave like integers. """ def __new__(cls, position, left, right): assert position == left or position == right obj = int.__new__(cls, position) obj._left = left obj._right = right return obj def __repr__(self): """String representation of the WithinPosition location for debugging.""" return "%s(%i, left=%i, right=%i)" \ % (self.__class__.__name__, int(self), self._left, self._right) def __str__(self): return "(%s^%s)" % (self._left, self._right) @property def position(self): """Legacy attribute to get (left) position as integer (OBSOLETE).""" return self._left @property def extension(self): """Legacy attribute to get extension (from left to right) as an integer (OBSOLETE).""" return self._right - self._left def _shift(self, offset): return self.__class__(int(self) + offset, self._left + offset, self._right + offset) def _flip(self, length): return self.__class__(length - int(self), length - self._right, length - self._left) class BeforePosition(int, AbstractPosition): """Specify a position where the actual location occurs before it. Arguments: o position - The upper boundary of where the location can occur. o extension - An optional argument which must be zero since we don't have an extension. The argument is provided so that the same number of arguments can be passed to all position types. This is used to specify positions like (<10..100) where the location occurs somewhere before position 10. >>> p = BeforePosition(5) >>> p BeforePosition(5) >>> print(p) <5 >>> int(p) 5 >>> p + 10 15 Note this potentially surprising behaviour: >>> p == ExactPosition(5) True >>> p == AfterPosition(5) True Just remember that for equality and sorting the position objects act like integers. """ # Subclasses int so can't use __init__ def __new__(cls, position, extension=0): if extension != 0: raise AttributeError("Non-zero extension %s for exact position." % extension) return int.__new__(cls, position) @property def position(self): """Legacy attribute to get position as integer (OBSOLETE).""" return int(self) @property def extension(self): """Legacy attribute to get extension (zero) as integer (OBSOLETE).""" return 0 def __repr__(self): """A string representation of the location for debugging.""" return "%s(%i)" % (self.__class__.__name__, int(self)) def __str__(self): return "<%s" % self.position def _shift(self, offset): return self.__class__(int(self) + offset) def _flip(self, length): return AfterPosition(length - int(self)) class AfterPosition(int, AbstractPosition): """Specify a position where the actual location is found after it. Arguments: o position - The lower boundary of where the location can occur. o extension - An optional argument which must be zero since we don't have an extension. The argument is provided so that the same number of arguments can be passed to all position types. This is used to specify positions like (>10..100) where the location occurs somewhere after position 10. >>> p = AfterPosition(7) >>> p AfterPosition(7) >>> print(p) >7 >>> int(p) 7 >>> p + 10 17 >>> isinstance(p, AfterPosition) True >>> isinstance(p, AbstractPosition) True >>> isinstance(p, int) True Note this potentially surprising behaviour: >>> p == ExactPosition(7) True >>> p == BeforePosition(7) True Just remember that for equality and sorting the position objects act like integers. """ # Subclasses int so can't use __init__ def __new__(cls, position, extension=0): if extension != 0: raise AttributeError("Non-zero extension %s for exact position." % extension) return int.__new__(cls, position) @property def position(self): """Legacy attribute to get position as integer (OBSOLETE).""" return int(self) @property def extension(self): """Legacy attribute to get extension (zero) as integer (OBSOLETE).""" return 0 def __repr__(self): """A string representation of the location for debugging.""" return "%s(%i)" % (self.__class__.__name__, int(self)) def __str__(self): return ">%s" % self.position def _shift(self, offset): return self.__class__(int(self) + offset) def _flip(self, length): return BeforePosition(length - int(self)) class OneOfPosition(int, AbstractPosition): """Specify a position where the location can be multiple positions. This models the GenBank 'one-of(1888,1901)' function, and tries to make this fit within the Biopython Position models. If this was a start position it should act like 1888, but as an end position 1901. >>> p = OneOfPosition(1888, [ExactPosition(1888), ExactPosition(1901)]) >>> p OneOfPosition(1888, choices=[ExactPosition(1888), ExactPosition(1901)]) >>> int(p) 1888 Interget comparisons and operators act like using int(p), >>> p == 1888 True >>> p <= 1888 True >>> p > 1888 False >>> p + 100 1988 >>> isinstance(p, OneOfPosition) True >>> isinstance(p, AbstractPosition) True >>> isinstance(p, int) True The old legacy properties of position and extension give the starting/lowest/left-most position as an integer, and the distance to the ending/highest/right-most position as an integer. Note that the position object will act like one of the list of possible locations depending on how it was created: >>> p2 = OneOfPosition(1901, [ExactPosition(1888), ExactPosition(1901)]) >>> p.position == p2.position == 1888 True >>> p.extension == p2.extension == 13 True >>> int(p) == int(p2) False >>> p == 1888 True >>> p2 == 1901 True """ def __new__(cls, position, choices): """Initialize with a set of posssible positions. position_list is a list of AbstractPosition derived objects, specifying possible locations. position is an integer specifying the default behaviour. """ assert position in choices, \ "OneOfPosition: %r should match one of %r" % (position, choices) obj = int.__new__(cls, position) obj.position_choices = choices return obj @property def position(self): """Legacy attribute to get (left) position as integer (OBSOLETE).""" return min(int(pos) for pos in self.position_choices) @property def extension(self): """Legacy attribute to get extension as integer (OBSOLETE).""" positions = [int(pos) for pos in self.position_choices] return max(positions) - min(positions) def __repr__(self): """String representation of the OneOfPosition location for debugging.""" return "%s(%i, choices=%r)" % (self.__class__.__name__, int(self), self.position_choices) def __str__(self): out = "one-of(" for position in self.position_choices: out += "%s," % position # replace the last comma with the closing parenthesis out = out[:-1] + ")" return out def _shift(self, offset): return self.__class__(int(self) + offset, [p._shift(offset) for p in self.position_choices]) def _flip(self, length): return self.__class__(length - int(self), [p._flip(length) for p in self.position_choices[::-1]]) class PositionGap(object): """Simple class to hold information about a gap between positions.""" def __init__(self, gap_size): """Intialize with a position object containing the gap information. """ self.gap_size = gap_size def __repr__(self): """A string representation of the position gap for debugging.""" return "%s(%s)" % (self.__class__.__name__, repr(self.gap_size)) def __str__(self): out = "gap(%s)" % self.gap_size return out if __name__ == "__main__": from Bio._utils import run_doctest run_doctest()