Source code for pyspark.ml.linalg

#
# Licensed to the Apache Software Foundation (ASF) under one or more
# contributor license agreements.  See the NOTICE file distributed with
# this work for additional information regarding copyright ownership.
# The ASF licenses this file to You under the Apache License, Version 2.0
# (the "License"); you may not use this file except in compliance with
# the License.  You may obtain a copy of the License at
#
#    http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#

"""
MLlib utilities for linear algebra. For dense vectors, MLlib
uses the NumPy C{array} type, so you can simply pass NumPy arrays
around. For sparse vectors, users can construct a L{SparseVector}
object from MLlib or pass SciPy C{scipy.sparse} column vectors if
SciPy is available in their environment.
"""

import sys
import array
import struct

if sys.version >= '3':
    basestring = str
    xrange = range
    import copyreg as copy_reg
    long = int
else:
    from itertools import izip as zip
    import copy_reg

import numpy as np

from pyspark import since
from pyspark.sql.types import UserDefinedType, StructField, StructType, ArrayType, DoubleType, \
    IntegerType, ByteType, BooleanType


__all__ = ['Vector', 'DenseVector', 'SparseVector', 'Vectors',
           'Matrix', 'DenseMatrix', 'SparseMatrix', 'Matrices']


if sys.version_info[:2] == (2, 7):
    # speed up pickling array in Python 2.7
    def fast_pickle_array(ar):
        return array.array, (ar.typecode, ar.tostring())
    copy_reg.pickle(array.array, fast_pickle_array)


# Check whether we have SciPy. MLlib works without it too, but if we have it, some methods,
# such as _dot and _serialize_double_vector, start to support scipy.sparse matrices.

try:
    import scipy.sparse
    _have_scipy = True
except:
    # No SciPy in environment, but that's okay
    _have_scipy = False


def _convert_to_vector(l):
    if isinstance(l, Vector):
        return l
    elif type(l) in (array.array, np.array, np.ndarray, list, tuple, xrange):
        return DenseVector(l)
    elif _have_scipy and scipy.sparse.issparse(l):
        assert l.shape[1] == 1, "Expected column vector"
        # Make sure the converted csc_matrix has sorted indices.
        csc = l.tocsc()
        if not csc.has_sorted_indices:
            csc.sort_indices()
        return SparseVector(l.shape[0], csc.indices, csc.data)
    else:
        raise TypeError("Cannot convert type %s into Vector" % type(l))


def _vector_size(v):
    """
    Returns the size of the vector.

    >>> _vector_size([1., 2., 3.])
    3
    >>> _vector_size((1., 2., 3.))
    3
    >>> _vector_size(array.array('d', [1., 2., 3.]))
    3
    >>> _vector_size(np.zeros(3))
    3
    >>> _vector_size(np.zeros((3, 1)))
    3
    >>> _vector_size(np.zeros((1, 3)))
    Traceback (most recent call last):
        ...
    ValueError: Cannot treat an ndarray of shape (1, 3) as a vector
    """
    if isinstance(v, Vector):
        return len(v)
    elif type(v) in (array.array, list, tuple, xrange):
        return len(v)
    elif type(v) == np.ndarray:
        if v.ndim == 1 or (v.ndim == 2 and v.shape[1] == 1):
            return len(v)
        else:
            raise ValueError("Cannot treat an ndarray of shape %s as a vector" % str(v.shape))
    elif _have_scipy and scipy.sparse.issparse(v):
        assert v.shape[1] == 1, "Expected column vector"
        return v.shape[0]
    else:
        raise TypeError("Cannot treat type %s as a vector" % type(v))


def _format_float(f, digits=4):
    s = str(round(f, digits))
    if '.' in s:
        s = s[:s.index('.') + 1 + digits]
    return s


def _format_float_list(l):
    return [_format_float(x) for x in l]


def _double_to_long_bits(value):
    if np.isnan(value):
        value = float('nan')
    # pack double into 64 bits, then unpack as long int
    return struct.unpack('Q', struct.pack('d', value))[0]


class VectorUDT(UserDefinedType):
    """
    SQL user-defined type (UDT) for Vector.
    """

    @classmethod
    def sqlType(cls):
        return StructType([
            StructField("type", ByteType(), False),
            StructField("size", IntegerType(), True),
            StructField("indices", ArrayType(IntegerType(), False), True),
            StructField("values", ArrayType(DoubleType(), False), True)])

    @classmethod
    def module(cls):
        return "pyspark.ml.linalg"

    @classmethod
    def scalaUDT(cls):
        return "org.apache.spark.ml.linalg.VectorUDT"

    def serialize(self, obj):
        if isinstance(obj, SparseVector):
            indices = [int(i) for i in obj.indices]
            values = [float(v) for v in obj.values]
            return (0, obj.size, indices, values)
        elif isinstance(obj, DenseVector):
            values = [float(v) for v in obj]
            return (1, None, None, values)
        else:
            raise TypeError("cannot serialize %r of type %r" % (obj, type(obj)))

    def deserialize(self, datum):
        assert len(datum) == 4, \
            "VectorUDT.deserialize given row with length %d but requires 4" % len(datum)
        tpe = datum[0]
        if tpe == 0:
            return SparseVector(datum[1], datum[2], datum[3])
        elif tpe == 1:
            return DenseVector(datum[3])
        else:
            raise ValueError("do not recognize type %r" % tpe)

    def simpleString(self):
        return "vector"


class MatrixUDT(UserDefinedType):
    """
    SQL user-defined type (UDT) for Matrix.
    """

    @classmethod
    def sqlType(cls):
        return StructType([
            StructField("type", ByteType(), False),
            StructField("numRows", IntegerType(), False),
            StructField("numCols", IntegerType(), False),
            StructField("colPtrs", ArrayType(IntegerType(), False), True),
            StructField("rowIndices", ArrayType(IntegerType(), False), True),
            StructField("values", ArrayType(DoubleType(), False), True),
            StructField("isTransposed", BooleanType(), False)])

    @classmethod
    def module(cls):
        return "pyspark.ml.linalg"

    @classmethod
    def scalaUDT(cls):
        return "org.apache.spark.ml.linalg.MatrixUDT"

    def serialize(self, obj):
        if isinstance(obj, SparseMatrix):
            colPtrs = [int(i) for i in obj.colPtrs]
            rowIndices = [int(i) for i in obj.rowIndices]
            values = [float(v) for v in obj.values]
            return (0, obj.numRows, obj.numCols, colPtrs,
                    rowIndices, values, bool(obj.isTransposed))
        elif isinstance(obj, DenseMatrix):
            values = [float(v) for v in obj.values]
            return (1, obj.numRows, obj.numCols, None, None, values,
                    bool(obj.isTransposed))
        else:
            raise TypeError("cannot serialize type %r" % (type(obj)))

    def deserialize(self, datum):
        assert len(datum) == 7, \
            "MatrixUDT.deserialize given row with length %d but requires 7" % len(datum)
        tpe = datum[0]
        if tpe == 0:
            return SparseMatrix(*datum[1:])
        elif tpe == 1:
            return DenseMatrix(datum[1], datum[2], datum[5], datum[6])
        else:
            raise ValueError("do not recognize type %r" % tpe)

    def simpleString(self):
        return "matrix"


[docs]class Vector(object): __UDT__ = VectorUDT() """ Abstract class for DenseVector and SparseVector """
[docs] def toArray(self): """ Convert the vector into an numpy.ndarray :return: numpy.ndarray """ raise NotImplementedError
[docs]class DenseVector(Vector): """ A dense vector represented by a value array. We use numpy array for storage and arithmetics will be delegated to the underlying numpy array. >>> v = Vectors.dense([1.0, 2.0]) >>> u = Vectors.dense([3.0, 4.0]) >>> v + u DenseVector([4.0, 6.0]) >>> 2 - v DenseVector([1.0, 0.0]) >>> v / 2 DenseVector([0.5, 1.0]) >>> v * u DenseVector([3.0, 8.0]) >>> u / v DenseVector([3.0, 2.0]) >>> u % 2 DenseVector([1.0, 0.0]) """ def __init__(self, ar): if isinstance(ar, bytes): ar = np.frombuffer(ar, dtype=np.float64) elif not isinstance(ar, np.ndarray): ar = np.array(ar, dtype=np.float64) if ar.dtype != np.float64: ar = ar.astype(np.float64) self.array = ar def __reduce__(self): return DenseVector, (self.array.tostring(),)
[docs] def numNonzeros(self): """ Number of nonzero elements. This scans all active values and count non zeros """ return np.count_nonzero(self.array)
[docs] def norm(self, p): """ Calculates the norm of a DenseVector. >>> a = DenseVector([0, -1, 2, -3]) >>> a.norm(2) 3.7... >>> a.norm(1) 6.0 """ return np.linalg.norm(self.array, p)
[docs] def dot(self, other): """ Compute the dot product of two Vectors. We support (Numpy array, list, SparseVector, or SciPy sparse) and a target NumPy array that is either 1- or 2-dimensional. Equivalent to calling numpy.dot of the two vectors. >>> dense = DenseVector(array.array('d', [1., 2.])) >>> dense.dot(dense) 5.0 >>> dense.dot(SparseVector(2, [0, 1], [2., 1.])) 4.0 >>> dense.dot(range(1, 3)) 5.0 >>> dense.dot(np.array(range(1, 3))) 5.0 >>> dense.dot([1.,]) Traceback (most recent call last): ... AssertionError: dimension mismatch >>> dense.dot(np.reshape([1., 2., 3., 4.], (2, 2), order='F')) array([ 5., 11.]) >>> dense.dot(np.reshape([1., 2., 3.], (3, 1), order='F')) Traceback (most recent call last): ... AssertionError: dimension mismatch """ if type(other) == np.ndarray: if other.ndim > 1: assert len(self) == other.shape[0], "dimension mismatch" return np.dot(self.array, other) elif _have_scipy and scipy.sparse.issparse(other): assert len(self) == other.shape[0], "dimension mismatch" return other.transpose().dot(self.toArray()) else: assert len(self) == _vector_size(other), "dimension mismatch" if isinstance(other, SparseVector): return other.dot(self) elif isinstance(other, Vector): return np.dot(self.toArray(), other.toArray()) else: return np.dot(self.toArray(), other)
[docs] def squared_distance(self, other): """ Squared distance of two Vectors. >>> dense1 = DenseVector(array.array('d', [1., 2.])) >>> dense1.squared_distance(dense1) 0.0 >>> dense2 = np.array([2., 1.]) >>> dense1.squared_distance(dense2) 2.0 >>> dense3 = [2., 1.] >>> dense1.squared_distance(dense3) 2.0 >>> sparse1 = SparseVector(2, [0, 1], [2., 1.]) >>> dense1.squared_distance(sparse1) 2.0 >>> dense1.squared_distance([1.,]) Traceback (most recent call last): ... AssertionError: dimension mismatch >>> dense1.squared_distance(SparseVector(1, [0,], [1.,])) Traceback (most recent call last): ... AssertionError: dimension mismatch """ assert len(self) == _vector_size(other), "dimension mismatch" if isinstance(other, SparseVector): return other.squared_distance(self) elif _have_scipy and scipy.sparse.issparse(other): return _convert_to_vector(other).squared_distance(self) if isinstance(other, Vector): other = other.toArray() elif not isinstance(other, np.ndarray): other = np.array(other) diff = self.toArray() - other return np.dot(diff, diff)
[docs] def toArray(self): """ Returns an numpy.ndarray """ return self.array
@property def values(self): """ Returns a list of values """ return self.array def __getitem__(self, item): return self.array[item] def __len__(self): return len(self.array) def __str__(self): return "[" + ",".join([str(v) for v in self.array]) + "]" def __repr__(self): return "DenseVector([%s])" % (', '.join(_format_float(i) for i in self.array)) def __eq__(self, other): if isinstance(other, DenseVector): return np.array_equal(self.array, other.array) elif isinstance(other, SparseVector): if len(self) != other.size: return False return Vectors._equals(list(xrange(len(self))), self.array, other.indices, other.values) return False def __ne__(self, other): return not self == other def __hash__(self): size = len(self) result = 31 + size nnz = 0 i = 0 while i < size and nnz < 128: if self.array[i] != 0: result = 31 * result + i bits = _double_to_long_bits(self.array[i]) result = 31 * result + (bits ^ (bits >> 32)) nnz += 1 i += 1 return result def __getattr__(self, item): return getattr(self.array, item) def _delegate(op): def func(self, other): if isinstance(other, DenseVector): other = other.array return DenseVector(getattr(self.array, op)(other)) return func __neg__ = _delegate("__neg__") __add__ = _delegate("__add__") __sub__ = _delegate("__sub__") __mul__ = _delegate("__mul__") __div__ = _delegate("__div__") __truediv__ = _delegate("__truediv__") __mod__ = _delegate("__mod__") __radd__ = _delegate("__radd__") __rsub__ = _delegate("__rsub__") __rmul__ = _delegate("__rmul__") __rdiv__ = _delegate("__rdiv__") __rtruediv__ = _delegate("__rtruediv__") __rmod__ = _delegate("__rmod__")
[docs]class SparseVector(Vector): """ A simple sparse vector class for passing data to MLlib. Users may alternatively pass SciPy's {scipy.sparse} data types. """ def __init__(self, size, *args): """ Create a sparse vector, using either a dictionary, a list of (index, value) pairs, or two separate arrays of indices and values (sorted by index). :param size: Size of the vector. :param args: Active entries, as a dictionary {index: value, ...}, a list of tuples [(index, value), ...], or a list of strictly increasing indices and a list of corresponding values [index, ...], [value, ...]. Inactive entries are treated as zeros. >>> SparseVector(4, {1: 1.0, 3: 5.5}) SparseVector(4, {1: 1.0, 3: 5.5}) >>> SparseVector(4, [(1, 1.0), (3, 5.5)]) SparseVector(4, {1: 1.0, 3: 5.5}) >>> SparseVector(4, [1, 3], [1.0, 5.5]) SparseVector(4, {1: 1.0, 3: 5.5}) >>> SparseVector(4, {1:1.0, 6:2.0}) Traceback (most recent call last): ... AssertionError: Index 6 is out of the size of vector with size=4 >>> SparseVector(4, {-1:1.0}) Traceback (most recent call last): ... AssertionError: Contains negative index -1 """ self.size = int(size) """ Size of the vector. """ assert 1 <= len(args) <= 2, "must pass either 2 or 3 arguments" if len(args) == 1: pairs = args[0] if type(pairs) == dict: pairs = pairs.items() pairs = sorted(pairs) self.indices = np.array([p[0] for p in pairs], dtype=np.int32) """ A list of indices corresponding to active entries. """ self.values = np.array([p[1] for p in pairs], dtype=np.float64) """ A list of values corresponding to active entries. """ else: if isinstance(args[0], bytes): assert isinstance(args[1], bytes), "values should be string too" if args[0]: self.indices = np.frombuffer(args[0], np.int32) self.values = np.frombuffer(args[1], np.float64) else: # np.frombuffer() doesn't work well with empty string in older version self.indices = np.array([], dtype=np.int32) self.values = np.array([], dtype=np.float64) else: self.indices = np.array(args[0], dtype=np.int32) self.values = np.array(args[1], dtype=np.float64) assert len(self.indices) == len(self.values), "index and value arrays not same length" for i in xrange(len(self.indices) - 1): if self.indices[i] >= self.indices[i + 1]: raise TypeError( "Indices %s and %s are not strictly increasing" % (self.indices[i], self.indices[i + 1])) if self.indices.size > 0: assert np.max(self.indices) < self.size, \ "Index %d is out of the size of vector with size=%d" \ % (np.max(self.indices), self.size) assert np.min(self.indices) >= 0, \ "Contains negative index %d" % (np.min(self.indices))
[docs] def numNonzeros(self): """ Number of nonzero elements. This scans all active values and count non zeros. """ return np.count_nonzero(self.values)
[docs] def norm(self, p): """ Calculates the norm of a SparseVector. >>> a = SparseVector(4, [0, 1], [3., -4.]) >>> a.norm(1) 7.0 >>> a.norm(2) 5.0 """ return np.linalg.norm(self.values, p)
def __reduce__(self): return ( SparseVector, (self.size, self.indices.tostring(), self.values.tostring()))
[docs] def dot(self, other): """ Dot product with a SparseVector or 1- or 2-dimensional Numpy array. >>> a = SparseVector(4, [1, 3], [3.0, 4.0]) >>> a.dot(a) 25.0 >>> a.dot(array.array('d', [1., 2., 3., 4.])) 22.0 >>> b = SparseVector(4, [2], [1.0]) >>> a.dot(b) 0.0 >>> a.dot(np.array([[1, 1], [2, 2], [3, 3], [4, 4]])) array([ 22., 22.]) >>> a.dot([1., 2., 3.]) Traceback (most recent call last): ... AssertionError: dimension mismatch >>> a.dot(np.array([1., 2.])) Traceback (most recent call last): ... AssertionError: dimension mismatch >>> a.dot(DenseVector([1., 2.])) Traceback (most recent call last): ... AssertionError: dimension mismatch >>> a.dot(np.zeros((3, 2))) Traceback (most recent call last): ... AssertionError: dimension mismatch """ if isinstance(other, np.ndarray): if other.ndim not in [2, 1]: raise ValueError("Cannot call dot with %d-dimensional array" % other.ndim) assert len(self) == other.shape[0], "dimension mismatch" return np.dot(self.values, other[self.indices]) assert len(self) == _vector_size(other), "dimension mismatch" if isinstance(other, DenseVector): return np.dot(other.array[self.indices], self.values) elif isinstance(other, SparseVector): # Find out common indices. self_cmind = np.in1d(self.indices, other.indices, assume_unique=True) self_values = self.values[self_cmind] if self_values.size == 0: return 0.0 else: other_cmind = np.in1d(other.indices, self.indices, assume_unique=True) return np.dot(self_values, other.values[other_cmind]) else: return self.dot(_convert_to_vector(other))
[docs] def squared_distance(self, other): """ Squared distance from a SparseVector or 1-dimensional NumPy array. >>> a = SparseVector(4, [1, 3], [3.0, 4.0]) >>> a.squared_distance(a) 0.0 >>> a.squared_distance(array.array('d', [1., 2., 3., 4.])) 11.0 >>> a.squared_distance(np.array([1., 2., 3., 4.])) 11.0 >>> b = SparseVector(4, [2], [1.0]) >>> a.squared_distance(b) 26.0 >>> b.squared_distance(a) 26.0 >>> b.squared_distance([1., 2.]) Traceback (most recent call last): ... AssertionError: dimension mismatch >>> b.squared_distance(SparseVector(3, [1,], [1.0,])) Traceback (most recent call last): ... AssertionError: dimension mismatch """ assert len(self) == _vector_size(other), "dimension mismatch" if isinstance(other, np.ndarray) or isinstance(other, DenseVector): if isinstance(other, np.ndarray) and other.ndim != 1: raise Exception("Cannot call squared_distance with %d-dimensional array" % other.ndim) if isinstance(other, DenseVector): other = other.array sparse_ind = np.zeros(other.size, dtype=bool) sparse_ind[self.indices] = True dist = other[sparse_ind] - self.values result = np.dot(dist, dist) other_ind = other[~sparse_ind] result += np.dot(other_ind, other_ind) return result elif isinstance(other, SparseVector): result = 0.0 i, j = 0, 0 while i < len(self.indices) and j < len(other.indices): if self.indices[i] == other.indices[j]: diff = self.values[i] - other.values[j] result += diff * diff i += 1 j += 1 elif self.indices[i] < other.indices[j]: result += self.values[i] * self.values[i] i += 1 else: result += other.values[j] * other.values[j] j += 1 while i < len(self.indices): result += self.values[i] * self.values[i] i += 1 while j < len(other.indices): result += other.values[j] * other.values[j] j += 1 return result else: return self.squared_distance(_convert_to_vector(other))
[docs] def toArray(self): """ Returns a copy of this SparseVector as a 1-dimensional NumPy array. """ arr = np.zeros((self.size,), dtype=np.float64) arr[self.indices] = self.values return arr
def __len__(self): return self.size def __str__(self): inds = "[" + ",".join([str(i) for i in self.indices]) + "]" vals = "[" + ",".join([str(v) for v in self.values]) + "]" return "(" + ",".join((str(self.size), inds, vals)) + ")" def __repr__(self): inds = self.indices vals = self.values entries = ", ".join(["{0}: {1}".format(inds[i], _format_float(vals[i])) for i in xrange(len(inds))]) return "SparseVector({0}, {{{1}}})".format(self.size, entries) def __eq__(self, other): if isinstance(other, SparseVector): return other.size == self.size and np.array_equal(other.indices, self.indices) \ and np.array_equal(other.values, self.values) elif isinstance(other, DenseVector): if self.size != len(other): return False return Vectors._equals(self.indices, self.values, list(xrange(len(other))), other.array) return False def __getitem__(self, index): inds = self.indices vals = self.values if not isinstance(index, int): raise TypeError( "Indices must be of type integer, got type %s" % type(index)) if index >= self.size or index < -self.size: raise IndexError("Index %d out of bounds." % index) if index < 0: index += self.size if (inds.size == 0) or (index > inds.item(-1)): return 0. insert_index = np.searchsorted(inds, index) row_ind = inds[insert_index] if row_ind == index: return vals[insert_index] return 0. def __ne__(self, other): return not self.__eq__(other) def __hash__(self): result = 31 + self.size nnz = 0 i = 0 while i < len(self.values) and nnz < 128: if self.values[i] != 0: result = 31 * result + int(self.indices[i]) bits = _double_to_long_bits(self.values[i]) result = 31 * result + (bits ^ (bits >> 32)) nnz += 1 i += 1 return result
[docs]class Vectors(object): """ Factory methods for working with vectors. .. note:: Dense vectors are simply represented as NumPy array objects, so there is no need to covert them for use in MLlib. For sparse vectors, the factory methods in this class create an MLlib-compatible type, or users can pass in SciPy's C{scipy.sparse} column vectors. """
[docs] @staticmethod def sparse(size, *args): """ Create a sparse vector, using either a dictionary, a list of (index, value) pairs, or two separate arrays of indices and values (sorted by index). :param size: Size of the vector. :param args: Non-zero entries, as a dictionary, list of tuples, or two sorted lists containing indices and values. >>> Vectors.sparse(4, {1: 1.0, 3: 5.5}) SparseVector(4, {1: 1.0, 3: 5.5}) >>> Vectors.sparse(4, [(1, 1.0), (3, 5.5)]) SparseVector(4, {1: 1.0, 3: 5.5}) >>> Vectors.sparse(4, [1, 3], [1.0, 5.5]) SparseVector(4, {1: 1.0, 3: 5.5}) """ return SparseVector(size, *args)
[docs] @staticmethod def dense(*elements): """ Create a dense vector of 64-bit floats from a Python list or numbers. >>> Vectors.dense([1, 2, 3]) DenseVector([1.0, 2.0, 3.0]) >>> Vectors.dense(1.0, 2.0) DenseVector([1.0, 2.0]) """ if len(elements) == 1 and not isinstance(elements[0], (float, int, long)): # it's list, numpy.array or other iterable object. elements = elements[0] return DenseVector(elements)
[docs] @staticmethod def squared_distance(v1, v2): """ Squared distance between two vectors. a and b can be of type SparseVector, DenseVector, np.ndarray or array.array. >>> a = Vectors.sparse(4, [(0, 1), (3, 4)]) >>> b = Vectors.dense([2, 5, 4, 1]) >>> a.squared_distance(b) 51.0 """ v1, v2 = _convert_to_vector(v1), _convert_to_vector(v2) return v1.squared_distance(v2)
[docs] @staticmethod def norm(vector, p): """ Find norm of the given vector. """ return _convert_to_vector(vector).norm(p)
[docs] @staticmethod def zeros(size): return DenseVector(np.zeros(size))
@staticmethod def _equals(v1_indices, v1_values, v2_indices, v2_values): """ Check equality between sparse/dense vectors, v1_indices and v2_indices assume to be strictly increasing. """ v1_size = len(v1_values) v2_size = len(v2_values) k1 = 0 k2 = 0 all_equal = True while all_equal: while k1 < v1_size and v1_values[k1] == 0: k1 += 1 while k2 < v2_size and v2_values[k2] == 0: k2 += 1 if k1 >= v1_size or k2 >= v2_size: return k1 >= v1_size and k2 >= v2_size all_equal = v1_indices[k1] == v2_indices[k2] and v1_values[k1] == v2_values[k2] k1 += 1 k2 += 1 return all_equal
[docs]class Matrix(object): __UDT__ = MatrixUDT() """ Represents a local matrix. """ def __init__(self, numRows, numCols, isTransposed=False): self.numRows = numRows self.numCols = numCols self.isTransposed = isTransposed
[docs] def toArray(self): """ Returns its elements in a NumPy ndarray. """ raise NotImplementedError
@staticmethod def _convert_to_array(array_like, dtype): """ Convert Matrix attributes which are array-like or buffer to array. """ if isinstance(array_like, bytes): return np.frombuffer(array_like, dtype=dtype) return np.asarray(array_like, dtype=dtype)
[docs]class DenseMatrix(Matrix): """ Column-major dense matrix. """ def __init__(self, numRows, numCols, values, isTransposed=False): Matrix.__init__(self, numRows, numCols, isTransposed) values = self._convert_to_array(values, np.float64) assert len(values) == numRows * numCols self.values = values def __reduce__(self): return DenseMatrix, ( self.numRows, self.numCols, self.values.tostring(), int(self.isTransposed)) def __str__(self): """ Pretty printing of a DenseMatrix >>> dm = DenseMatrix(2, 2, range(4)) >>> print(dm) DenseMatrix([[ 0., 2.], [ 1., 3.]]) >>> dm = DenseMatrix(2, 2, range(4), isTransposed=True) >>> print(dm) DenseMatrix([[ 0., 1.], [ 2., 3.]]) """ # Inspired by __repr__ in scipy matrices. array_lines = repr(self.toArray()).splitlines() # We need to adjust six spaces which is the difference in number # of letters between "DenseMatrix" and "array" x = '\n'.join([(" " * 6 + line) for line in array_lines[1:]]) return array_lines[0].replace("array", "DenseMatrix") + "\n" + x def __repr__(self): """ Representation of a DenseMatrix >>> dm = DenseMatrix(2, 2, range(4)) >>> dm DenseMatrix(2, 2, [0.0, 1.0, 2.0, 3.0], False) """ # If the number of values are less than seventeen then return as it is. # Else return first eight values and last eight values. if len(self.values) < 17: entries = _format_float_list(self.values) else: entries = ( _format_float_list(self.values[:8]) + ["..."] + _format_float_list(self.values[-8:]) ) entries = ", ".join(entries) return "DenseMatrix({0}, {1}, [{2}], {3})".format( self.numRows, self.numCols, entries, self.isTransposed)
[docs] def toArray(self): """ Return an numpy.ndarray >>> m = DenseMatrix(2, 2, range(4)) >>> m.toArray() array([[ 0., 2.], [ 1., 3.]]) """ if self.isTransposed: return np.asfortranarray( self.values.reshape((self.numRows, self.numCols))) else: return self.values.reshape((self.numRows, self.numCols), order='F')
[docs] def toSparse(self): """Convert to SparseMatrix""" if self.isTransposed: values = np.ravel(self.toArray(), order='F') else: values = self.values indices = np.nonzero(values)[0] colCounts = np.bincount(indices // self.numRows) colPtrs = np.cumsum(np.hstack( (0, colCounts, np.zeros(self.numCols - colCounts.size)))) values = values[indices] rowIndices = indices % self.numRows return SparseMatrix(self.numRows, self.numCols, colPtrs, rowIndices, values)
def __getitem__(self, indices): i, j = indices if i < 0 or i >= self.numRows: raise IndexError("Row index %d is out of range [0, %d)" % (i, self.numRows)) if j >= self.numCols or j < 0: raise IndexError("Column index %d is out of range [0, %d)" % (j, self.numCols)) if self.isTransposed: return self.values[i * self.numCols + j] else: return self.values[i + j * self.numRows] def __eq__(self, other): if (not isinstance(other, DenseMatrix) or self.numRows != other.numRows or self.numCols != other.numCols): return False self_values = np.ravel(self.toArray(), order='F') other_values = np.ravel(other.toArray(), order='F') return all(self_values == other_values)
[docs]class SparseMatrix(Matrix): """Sparse Matrix stored in CSC format.""" def __init__(self, numRows, numCols, colPtrs, rowIndices, values, isTransposed=False): Matrix.__init__(self, numRows, numCols, isTransposed) self.colPtrs = self._convert_to_array(colPtrs, np.int32) self.rowIndices = self._convert_to_array(rowIndices, np.int32) self.values = self._convert_to_array(values, np.float64) if self.isTransposed: if self.colPtrs.size != numRows + 1: raise ValueError("Expected colPtrs of size %d, got %d." % (numRows + 1, self.colPtrs.size)) else: if self.colPtrs.size != numCols + 1: raise ValueError("Expected colPtrs of size %d, got %d." % (numCols + 1, self.colPtrs.size)) if self.rowIndices.size != self.values.size: raise ValueError("Expected rowIndices of length %d, got %d." % (self.rowIndices.size, self.values.size)) def __str__(self): """ Pretty printing of a SparseMatrix >>> sm1 = SparseMatrix(2, 2, [0, 2, 3], [0, 1, 1], [2, 3, 4]) >>> print(sm1) 2 X 2 CSCMatrix (0,0) 2.0 (1,0) 3.0 (1,1) 4.0 >>> sm1 = SparseMatrix(2, 2, [0, 2, 3], [0, 1, 1], [2, 3, 4], True) >>> print(sm1) 2 X 2 CSRMatrix (0,0) 2.0 (0,1) 3.0 (1,1) 4.0 """ spstr = "{0} X {1} ".format(self.numRows, self.numCols) if self.isTransposed: spstr += "CSRMatrix\n" else: spstr += "CSCMatrix\n" cur_col = 0 smlist = [] # Display first 16 values. if len(self.values) <= 16: zipindval = zip(self.rowIndices, self.values) else: zipindval = zip(self.rowIndices[:16], self.values[:16]) for i, (rowInd, value) in enumerate(zipindval): if self.colPtrs[cur_col + 1] <= i: cur_col += 1 if self.isTransposed: smlist.append('({0},{1}) {2}'.format( cur_col, rowInd, _format_float(value))) else: smlist.append('({0},{1}) {2}'.format( rowInd, cur_col, _format_float(value))) spstr += "\n".join(smlist) if len(self.values) > 16: spstr += "\n.." * 2 return spstr def __repr__(self): """ Representation of a SparseMatrix >>> sm1 = SparseMatrix(2, 2, [0, 2, 3], [0, 1, 1], [2, 3, 4]) >>> sm1 SparseMatrix(2, 2, [0, 2, 3], [0, 1, 1], [2.0, 3.0, 4.0], False) """ rowIndices = list(self.rowIndices) colPtrs = list(self.colPtrs) if len(self.values) <= 16: values = _format_float_list(self.values) else: values = ( _format_float_list(self.values[:8]) + ["..."] + _format_float_list(self.values[-8:]) ) rowIndices = rowIndices[:8] + ["..."] + rowIndices[-8:] if len(self.colPtrs) > 16: colPtrs = colPtrs[:8] + ["..."] + colPtrs[-8:] values = ", ".join(values) rowIndices = ", ".join([str(ind) for ind in rowIndices]) colPtrs = ", ".join([str(ptr) for ptr in colPtrs]) return "SparseMatrix({0}, {1}, [{2}], [{3}], [{4}], {5})".format( self.numRows, self.numCols, colPtrs, rowIndices, values, self.isTransposed) def __reduce__(self): return SparseMatrix, ( self.numRows, self.numCols, self.colPtrs.tostring(), self.rowIndices.tostring(), self.values.tostring(), int(self.isTransposed)) def __getitem__(self, indices): i, j = indices if i < 0 or i >= self.numRows: raise IndexError("Row index %d is out of range [0, %d)" % (i, self.numRows)) if j < 0 or j >= self.numCols: raise IndexError("Column index %d is out of range [0, %d)" % (j, self.numCols)) # If a CSR matrix is given, then the row index should be searched # for in ColPtrs, and the column index should be searched for in the # corresponding slice obtained from rowIndices. if self.isTransposed: j, i = i, j colStart = self.colPtrs[j] colEnd = self.colPtrs[j + 1] nz = self.rowIndices[colStart: colEnd] ind = np.searchsorted(nz, i) + colStart if ind < colEnd and self.rowIndices[ind] == i: return self.values[ind] else: return 0.0
[docs] def toArray(self): """ Return an numpy.ndarray """ A = np.zeros((self.numRows, self.numCols), dtype=np.float64, order='F') for k in xrange(self.colPtrs.size - 1): startptr = self.colPtrs[k] endptr = self.colPtrs[k + 1] if self.isTransposed: A[k, self.rowIndices[startptr:endptr]] = self.values[startptr:endptr] else: A[self.rowIndices[startptr:endptr], k] = self.values[startptr:endptr] return A
[docs] def toDense(self): densevals = np.ravel(self.toArray(), order='F') return DenseMatrix(self.numRows, self.numCols, densevals)
# TODO: More efficient implementation: def __eq__(self, other): return np.all(self.toArray() == other.toArray())
[docs]class Matrices(object):
[docs] @staticmethod def dense(numRows, numCols, values): """ Create a DenseMatrix """ return DenseMatrix(numRows, numCols, values)
[docs] @staticmethod def sparse(numRows, numCols, colPtrs, rowIndices, values): """ Create a SparseMatrix """ return SparseMatrix(numRows, numCols, colPtrs, rowIndices, values)
def _test(): import doctest (failure_count, test_count) = doctest.testmod(optionflags=doctest.ELLIPSIS) if failure_count: exit(-1) if __name__ == "__main__": _test()