# Copyright (C) 2013 Oskar Maier
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
#
# author Oskar Maier
# version r0.1.1
# since 2014-03-13
# status Release
# build-in modules
# third-party modules
import numpy
from scipy.ndimage import _ni_support
from scipy.ndimage.morphology import distance_transform_edt, binary_erosion,\
generate_binary_structure
from scipy.ndimage.measurements import label, find_objects
from scipy.stats import pearsonr
# own modules
# code
def dc(result, reference):
r"""
Dice coefficient
Computes the Dice coefficient (also known as Sorensen index) between the binary
objects in two images.
The metric is defined as
.. math::
DC=\frac{2|A\cap B|}{|A|+|B|}
, where :math:`A` is the first and :math:`B` the second set of samples (here: binary objects).
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
Returns
-------
dc : float
The Dice coefficient between the object(s) in ```result``` and the
object(s) in ```reference```. It ranges from 0 (no overlap) to 1 (perfect overlap).
Notes
-----
This is a real metric. The binary images can therefore be supplied in any order.
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
intersection = numpy.count_nonzero(result & reference)
size_i1 = numpy.count_nonzero(result)
size_i2 = numpy.count_nonzero(reference)
try:
dc = 2. * intersection / float(size_i1 + size_i2)
except ZeroDivisionError:
dc = 0.0
return dc
def jc(result, reference):
"""
Jaccard coefficient
Computes the Jaccard coefficient between the binary objects in two images.
Parameters
----------
result: array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference: array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
Returns
-------
jc: float
The Jaccard coefficient between the object(s) in `result` and the
object(s) in `reference`. It ranges from 0 (no overlap) to 1 (perfect overlap).
Notes
-----
This is a real metric. The binary images can therefore be supplied in any order.
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
intersection = numpy.count_nonzero(result & reference)
union = numpy.count_nonzero(result | reference)
jc = float(intersection) / float(union)
return jc
def precision(result, reference):
"""
Precison.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
Returns
-------
precision : float
The precision between two binary datasets, here mostly binary objects in images,
which is defined as the fraction of retrieved instances that are relevant. The
precision is not symmetric.
See also
--------
:func:`recall`
Notes
-----
Not symmetric. The inverse of the precision is :func:`recall`.
High precision means that an algorithm returned substantially more relevant results than irrelevant.
References
----------
.. [1] http://en.wikipedia.org/wiki/Precision_and_recall
.. [2] http://en.wikipedia.org/wiki/Confusion_matrix#Table_of_confusion
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
tp = numpy.count_nonzero(result & reference)
fp = numpy.count_nonzero(result & ~reference)
try:
precision = tp / float(tp + fp)
except ZeroDivisionError:
precision = 0.0
return precision
def recall(result, reference):
"""
Recall.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
Returns
-------
recall : float
The recall between two binary datasets, here mostly binary objects in images,
which is defined as the fraction of relevant instances that are retrieved. The
recall is not symmetric.
See also
--------
:func:`precision`
Notes
-----
Not symmetric. The inverse of the recall is :func:`precision`.
High recall means that an algorithm returned most of the relevant results.
References
----------
.. [1] http://en.wikipedia.org/wiki/Precision_and_recall
.. [2] http://en.wikipedia.org/wiki/Confusion_matrix#Table_of_confusion
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
tp = numpy.count_nonzero(result & reference)
fn = numpy.count_nonzero(~result & reference)
try:
recall = tp / float(tp + fn)
except ZeroDivisionError:
recall = 0.0
return recall
def sensitivity(result, reference):
"""
Sensitivity.
Same as :func:`recall`, see there for a detailed description.
See also
--------
:func:`specificity`
"""
return recall(result, reference)
def specificity(result, reference):
"""
Specificity.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
Returns
-------
specificity : float
The specificity between two binary datasets, here mostly binary objects in images,
which denotes the fraction of correctly returned negatives. The
specificity is not symmetric.
See also
--------
:func:`sensitivity`
Notes
-----
Not symmetric. The completment of the specificity is :func:`sensitivity`.
High recall means that an algorithm returned most of the irrelevant results.
References
----------
.. [1] https://en.wikipedia.org/wiki/Sensitivity_and_specificity
.. [2] http://en.wikipedia.org/wiki/Confusion_matrix#Table_of_confusion
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
tn = numpy.count_nonzero(~result & ~reference)
fp = numpy.count_nonzero(result & ~reference)
try:
specificity = tn / float(tn + fp)
except ZeroDivisionError:
specificity = 0.0
return specificity
def true_negative_rate(result, reference):
"""
True negative rate.
Same as :func:`sensitivity`, see there for a detailed description.
See also
--------
:func:`true_positive_rate`
:func:`positive_predictive_value`
"""
return sensitivity(result, reference)
def true_positive_rate(result, reference):
"""
True positive rate.
Same as :func:`recall`, see there for a detailed description.
See also
--------
:func:`positive_predictive_value`
:func:`true_negative_rate`
"""
return recall(result, reference)
def positive_predictive_value(result, reference):
"""
Positive predictive value.
Same as :func:`precision`, see there for a detailed description.
See also
--------
:func:`true_positive_rate`
:func:`true_negative_rate`
"""
return precision(result, reference)
def hd(result, reference, voxelspacing=None, connectivity=1):
"""
Hausdorff Distance.
Computes the (symmetric) Hausdorff Distance (HD) between the binary objects in two
images. It is defined as the maximum surface distance between the objects.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
voxelspacing : float or sequence of floats, optional
The voxelspacing in a distance unit i.e. spacing of elements
along each dimension. If a sequence, must be of length equal to
the input rank; if a single number, this is used for all axes. If
not specified, a grid spacing of unity is implied.
connectivity : int
The neighbourhood/connectivity considered when determining the surface
of the binary objects. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
Note that the connectivity influences the result in the case of the Hausdorff distance.
Returns
-------
hd : float
The symmetric Hausdorff Distance between the object(s) in ```result``` and the
object(s) in ```reference```. The distance unit is the same as for the spacing of
elements along each dimension, which is usually given in mm.
See also
--------
:func:`assd`
:func:`asd`
Notes
-----
This is a real metric. The binary images can therefore be supplied in any order.
"""
hd1 = __surface_distances(result, reference, voxelspacing, connectivity).max()
hd2 = __surface_distances(reference, result, voxelspacing, connectivity).max()
hd = max(hd1, hd2)
return hd
def hd95(result, reference, voxelspacing=None, connectivity=1):
"""
95th percentile of the Hausdorff Distance.
Computes the 95th percentile of the (symmetric) Hausdorff Distance (HD) between the binary objects in two
images. Compared to the Hausdorff Distance, this metric is slightly more stable to small outliers and is
commonly used in Biomedical Segmentation challenges.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
voxelspacing : float or sequence of floats, optional
The voxelspacing in a distance unit i.e. spacing of elements
along each dimension. If a sequence, must be of length equal to
the input rank; if a single number, this is used for all axes. If
not specified, a grid spacing of unity is implied.
connectivity : int
The neighbourhood/connectivity considered when determining the surface
of the binary objects. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
Note that the connectivity influences the result in the case of the Hausdorff distance.
Returns
-------
hd : float
The symmetric Hausdorff Distance between the object(s) in ```result``` and the
object(s) in ```reference```. The distance unit is the same as for the spacing of
elements along each dimension, which is usually given in mm.
See also
--------
:func:`hd`
Notes
-----
This is a real metric. The binary images can therefore be supplied in any order.
"""
hd1 = __surface_distances(result, reference, voxelspacing, connectivity)
hd2 = __surface_distances(reference, result, voxelspacing, connectivity)
hd95 = numpy.percentile(numpy.hstack((hd1, hd2)), 95)
return hd95
def assd(result, reference, voxelspacing=None, connectivity=1):
"""
Average symmetric surface distance.
Computes the average symmetric surface distance (ASD) between the binary objects in
two images.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
voxelspacing : float or sequence of floats, optional
The voxelspacing in a distance unit i.e. spacing of elements
along each dimension. If a sequence, must be of length equal to
the input rank; if a single number, this is used for all axes. If
not specified, a grid spacing of unity is implied.
connectivity : int
The neighbourhood/connectivity considered when determining the surface
of the binary objects. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
The decision on the connectivity is important, as it can influence the results
strongly. If in doubt, leave it as it is.
Returns
-------
assd : float
The average symmetric surface distance between the object(s) in ``result`` and the
object(s) in ``reference``. The distance unit is the same as for the spacing of
elements along each dimension, which is usually given in mm.
See also
--------
:func:`asd`
:func:`hd`
Notes
-----
This is a real metric, obtained by calling and averaging
>>> asd(result, reference)
and
>>> asd(reference, result)
The binary images can therefore be supplied in any order.
"""
assd = numpy.mean( (asd(result, reference, voxelspacing, connectivity), asd(reference, result, voxelspacing, connectivity)) )
return assd
def asd(result, reference, voxelspacing=None, connectivity=1):
"""
Average surface distance metric.
Computes the average surface distance (ASD) between the binary objects in two images.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
voxelspacing : float or sequence of floats, optional
The voxelspacing in a distance unit i.e. spacing of elements
along each dimension. If a sequence, must be of length equal to
the input rank; if a single number, this is used for all axes. If
not specified, a grid spacing of unity is implied.
connectivity : int
The neighbourhood/connectivity considered when determining the surface
of the binary objects. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
The decision on the connectivity is important, as it can influence the results
strongly. If in doubt, leave it as it is.
Returns
-------
asd : float
The average surface distance between the object(s) in ``result`` and the
object(s) in ``reference``. The distance unit is the same as for the spacing
of elements along each dimension, which is usually given in mm.
See also
--------
:func:`assd`
:func:`hd`
Notes
-----
This is not a real metric, as it is directed. See `assd` for a real metric of this.
The method is implemented making use of distance images and simple binary morphology
to achieve high computational speed.
Examples
--------
The `connectivity` determines what pixels/voxels are considered the surface of a
binary object. Take the following binary image showing a cross
>>> from scipy.ndimage.morphology import generate_binary_structure
>>> cross = generate_binary_structure(2, 1)
array([[0, 1, 0],
[1, 1, 1],
[0, 1, 0]])
With `connectivity` set to `1` a 4-neighbourhood is considered when determining the
object surface, resulting in the surface
.. code-block:: python
array([[0, 1, 0],
[1, 0, 1],
[0, 1, 0]])
Changing `connectivity` to `2`, a 8-neighbourhood is considered and we get:
.. code-block:: python
array([[0, 1, 0],
[1, 1, 1],
[0, 1, 0]])
, as a diagonal connection does no longer qualifies as valid object surface.
This influences the results `asd` returns. Imagine we want to compute the surface
distance of our cross to a cube-like object:
>>> cube = generate_binary_structure(2, 1)
array([[1, 1, 1],
[1, 1, 1],
[1, 1, 1]])
, which surface is, independent of the `connectivity` value set, always
.. code-block:: python
array([[1, 1, 1],
[1, 0, 1],
[1, 1, 1]])
Using a `connectivity` of `1` we get
>>> asd(cross, cube, connectivity=1)
0.0
while a value of `2` returns us
>>> asd(cross, cube, connectivity=2)
0.20000000000000001
due to the center of the cross being considered surface as well.
"""
sds = __surface_distances(result, reference, voxelspacing, connectivity)
asd = sds.mean()
return asd
def ravd(result, reference):
"""
Relative absolute volume difference.
Compute the relative absolute volume difference between the (joined) binary objects
in the two images.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
Returns
-------
ravd : float
The relative absolute volume difference between the object(s) in ``result``
and the object(s) in ``reference``. This is a percentage value in the range
:math:`[-1.0, +inf]` for which a :math:`0` denotes an ideal score.
Raises
------
RuntimeError
If the reference object is empty.
See also
--------
:func:`dc`
:func:`precision`
:func:`recall`
Notes
-----
This is not a real metric, as it is directed. Negative values denote a smaller
and positive values a larger volume than the reference.
This implementation does not check, whether the two supplied arrays are of the same
size.
Examples
--------
Considering the following inputs
>>> import numpy
>>> arr1 = numpy.asarray([[0,1,0],[1,1,1],[0,1,0]])
>>> arr1
array([[0, 1, 0],
[1, 1, 1],
[0, 1, 0]])
>>> arr2 = numpy.asarray([[0,1,0],[1,0,1],[0,1,0]])
>>> arr2
array([[0, 1, 0],
[1, 0, 1],
[0, 1, 0]])
comparing `arr1` to `arr2` we get
>>> ravd(arr1, arr2)
-0.2
and reversing the inputs the directivness of the metric becomes evident
>>> ravd(arr2, arr1)
0.25
It is important to keep in mind that a perfect score of `0` does not mean that the
binary objects fit exactely, as only the volumes are compared:
>>> arr1 = numpy.asarray([1,0,0])
>>> arr2 = numpy.asarray([0,0,1])
>>> ravd(arr1, arr2)
0.0
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
vol1 = numpy.count_nonzero(result)
vol2 = numpy.count_nonzero(reference)
if 0 == vol2:
raise RuntimeError('The second supplied array does not contain any binary object.')
return (vol1 - vol2) / float(vol2)
def volume_correlation(results, references):
r"""
Volume correlation.
Computes the linear correlation in binary object volume between the
contents of the successive binary images supplied. Measured through
the Pearson product-moment correlation coefficient.
Parameters
----------
results : sequence of array_like
Ordered list of input data containing objects. Each array_like will be
converted into binary: background where 0, object everywhere else.
references : sequence of array_like
Ordered list of input data containing objects. Each array_like will be
converted into binary: background where 0, object everywhere else.
The order must be the same as for ``results``.
Returns
-------
r : float
The correlation coefficient between -1 and 1.
p : float
The two-side p value.
"""
results = numpy.atleast_2d(numpy.array(results).astype(numpy.bool))
references = numpy.atleast_2d(numpy.array(references).astype(numpy.bool))
results_volumes = [numpy.count_nonzero(r) for r in results]
references_volumes = [numpy.count_nonzero(r) for r in references]
return pearsonr(results_volumes, references_volumes) # returns (Pearson'
def volume_change_correlation(results, references):
r"""
Volume change correlation.
Computes the linear correlation of change in binary object volume between
the contents of the successive binary images supplied. Measured through
the Pearson product-moment correlation coefficient.
Parameters
----------
results : sequence of array_like
Ordered list of input data containing objects. Each array_like will be
converted into binary: background where 0, object everywhere else.
references : sequence of array_like
Ordered list of input data containing objects. Each array_like will be
converted into binary: background where 0, object everywhere else.
The order must be the same as for ``results``.
Returns
-------
r : float
The correlation coefficient between -1 and 1.
p : float
The two-side p value.
"""
results = numpy.atleast_2d(numpy.array(results).astype(numpy.bool))
references = numpy.atleast_2d(numpy.array(references).astype(numpy.bool))
results_volumes = numpy.asarray([numpy.count_nonzero(r) for r in results])
references_volumes = numpy.asarray([numpy.count_nonzero(r) for r in references])
results_volumes_changes = results_volumes[1:] - results_volumes[:-1]
references_volumes_changes = references_volumes[1:] - references_volumes[:-1]
return pearsonr(results_volumes_changes, references_volumes_changes) # returns (Pearson's correlation coefficient, 2-tailed p-value)
def obj_assd(result, reference, voxelspacing=None, connectivity=1):
"""
Average symmetric surface distance.
Computes the average symmetric surface distance (ASSD) between the binary objects in
two images.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
voxelspacing : float or sequence of floats, optional
The voxelspacing in a distance unit i.e. spacing of elements
along each dimension. If a sequence, must be of length equal to
the input rank; if a single number, this is used for all axes. If
not specified, a grid spacing of unity is implied.
connectivity : int
The neighbourhood/connectivity considered when determining what accounts
for a distinct binary object as well as when determining the surface
of the binary objects. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
The decision on the connectivity is important, as it can influence the results
strongly. If in doubt, leave it as it is.
Returns
-------
assd : float
The average symmetric surface distance between all mutually existing distinct
binary object(s) in ``result`` and ``reference``. The distance unit is the same as for
the spacing of elements along each dimension, which is usually given in mm.
See also
--------
:func:`obj_asd`
Notes
-----
This is a real metric, obtained by calling and averaging
>>> obj_asd(result, reference)
and
>>> obj_asd(reference, result)
The binary images can therefore be supplied in any order.
"""
assd = numpy.mean( (obj_asd(result, reference, voxelspacing, connectivity), obj_asd(reference, result, voxelspacing, connectivity)) )
return assd
def obj_asd(result, reference, voxelspacing=None, connectivity=1):
"""
Average surface distance between objects.
First correspondences between distinct binary objects in reference and result are
established. Then the average surface distance is only computed between corresponding
objects. Correspondence is defined as unique and at least one voxel overlap.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
voxelspacing : float or sequence of floats, optional
The voxelspacing in a distance unit i.e. spacing of elements
along each dimension. If a sequence, must be of length equal to
the input rank; if a single number, this is used for all axes. If
not specified, a grid spacing of unity is implied.
connectivity : int
The neighbourhood/connectivity considered when determining what accounts
for a distinct binary object as well as when determining the surface
of the binary objects. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
The decision on the connectivity is important, as it can influence the results
strongly. If in doubt, leave it as it is.
Returns
-------
asd : float
The average surface distance between all mutually existing distinct binary
object(s) in ``result`` and ``reference``. The distance unit is the same as for the
spacing of elements along each dimension, which is usually given in mm.
See also
--------
:func:`obj_assd`
:func:`obj_tpr`
:func:`obj_fpr`
Notes
-----
This is not a real metric, as it is directed. See `obj_assd` for a real metric of this.
For the understanding of this metric, both the notions of connectedness and surface
distance are essential. Please see :func:`obj_tpr` and :func:`obj_fpr` for more
information on the first and :func:`asd` on the second.
Examples
--------
>>> arr1 = numpy.asarray([[1,1,1],[1,1,1],[1,1,1]])
>>> arr2 = numpy.asarray([[0,1,0],[0,1,0],[0,1,0]])
>>> arr1
array([[1, 1, 1],
[1, 1, 1],
[1, 1, 1]])
>>> arr2
array([[0, 1, 0],
[0, 1, 0],
[0, 1, 0]])
>>> obj_asd(arr1, arr2)
1.5
>>> obj_asd(arr2, arr1)
0.333333333333
With the `voxelspacing` parameter, the distances between the voxels can be set for
each dimension separately:
>>> obj_asd(arr1, arr2, voxelspacing=(1,2))
1.5
>>> obj_asd(arr2, arr1, voxelspacing=(1,2))
0.333333333333
More examples depicting the notion of object connectedness:
>>> arr1 = numpy.asarray([[1,0,1],[1,0,0],[0,0,0]])
>>> arr2 = numpy.asarray([[1,0,1],[1,0,0],[0,0,1]])
>>> arr1
array([[1, 0, 1],
[1, 0, 0],
[0, 0, 0]])
>>> arr2
array([[1, 0, 1],
[1, 0, 0],
[0, 0, 1]])
>>> obj_asd(arr1, arr2)
0.0
>>> obj_asd(arr2, arr1)
0.0
>>> arr1 = numpy.asarray([[1,0,1],[1,0,1],[0,0,1]])
>>> arr2 = numpy.asarray([[1,0,1],[1,0,0],[0,0,1]])
>>> arr1
array([[1, 0, 1],
[1, 0, 1],
[0, 0, 1]])
>>> arr2
array([[1, 0, 1],
[1, 0, 0],
[0, 0, 1]])
>>> obj_asd(arr1, arr2)
0.6
>>> obj_asd(arr2, arr1)
0.0
Influence of `connectivity` parameter can be seen in the following example, where
with the (default) connectivity of `1` the first array is considered to contain two
objects, while with an increase connectivity of `2`, just one large object is
detected.
>>> arr1 = numpy.asarray([[1,0,0],[0,1,1],[0,1,1]])
>>> arr2 = numpy.asarray([[1,0,0],[0,0,0],[0,0,0]])
>>> arr1
array([[1, 0, 0],
[0, 1, 1],
[0, 1, 1]])
>>> arr2
array([[1, 0, 0],
[0, 0, 0],
[0, 0, 0]])
>>> obj_asd(arr1, arr2)
0.0
>>> obj_asd(arr1, arr2, connectivity=2)
1.742955328
Note that the connectivity also influence the notion of what is considered an object
surface voxels.
"""
sds = list()
labelmap1, labelmap2, _a, _b, mapping = __distinct_binary_object_correspondences(result, reference, connectivity)
slicers1 = find_objects(labelmap1)
slicers2 = find_objects(labelmap2)
for lid2, lid1 in mapping.items():
window = __combine_windows(slicers1[lid1 - 1], slicers2[lid2 - 1])
object1 = labelmap1[window] == lid1
object2 = labelmap2[window] == lid2
sds.extend(__surface_distances(object1, object2, voxelspacing, connectivity))
asd = numpy.mean(sds)
return asd
def obj_fpr(result, reference, connectivity=1):
"""
The false positive rate of distinct binary object detection.
The false positive rates gives a percentage measure of how many distinct binary
objects in the second array do not exists in the first array. A partial overlap
(of minimum one voxel) is here considered sufficient.
In cases where two distinct binary object in the second array overlap with a single
distinct object in the first array, only one is considered to have been detected
successfully and the other is added to the count of false positives.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
connectivity : int
The neighbourhood/connectivity considered when determining what accounts
for a distinct binary object. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
The decision on the connectivity is important, as it can influence the results
strongly. If in doubt, leave it as it is.
Returns
-------
tpr : float
A percentage measure of how many distinct binary objects in ``results`` have no
corresponding binary object in ``reference``. It has the range :math:`[0, 1]`, where a :math:`0`
denotes an ideal score.
Raises
------
RuntimeError
If the second array is empty.
See also
--------
:func:`obj_tpr`
Notes
-----
This is not a real metric, as it is directed. Whatever array is considered as
reference should be passed second. A perfect score of :math:`0` tells that there are no
distinct binary objects in the second array that do not exists also in the reference
array, but does not reveal anything about objects in the reference array also
existing in the second array (use :func:`obj_tpr` for this).
Examples
--------
>>> arr2 = numpy.asarray([[1,0,0],[1,0,1],[0,0,1]])
>>> arr1 = numpy.asarray([[0,0,1],[1,0,1],[0,0,1]])
>>> arr2
array([[1, 0, 0],
[1, 0, 1],
[0, 0, 1]])
>>> arr1
array([[0, 0, 1],
[1, 0, 1],
[0, 0, 1]])
>>> obj_fpr(arr1, arr2)
0.0
>>> obj_fpr(arr2, arr1)
0.0
Example of directedness:
>>> arr2 = numpy.asarray([1,0,1,0,1])
>>> arr1 = numpy.asarray([1,0,1,0,0])
>>> obj_fpr(arr1, arr2)
0.0
>>> obj_fpr(arr2, arr1)
0.3333333333333333
Examples of multiple overlap treatment:
>>> arr2 = numpy.asarray([1,0,1,0,1,1,1])
>>> arr1 = numpy.asarray([1,1,1,0,1,0,1])
>>> obj_fpr(arr1, arr2)
0.3333333333333333
>>> obj_fpr(arr2, arr1)
0.3333333333333333
>>> arr2 = numpy.asarray([1,0,1,1,1,0,1])
>>> arr1 = numpy.asarray([1,1,1,0,1,1,1])
>>> obj_fpr(arr1, arr2)
0.0
>>> obj_fpr(arr2, arr1)
0.3333333333333333
>>> arr2 = numpy.asarray([[1,0,1,0,0],
[1,0,0,0,0],
[1,0,1,1,1],
[0,0,0,0,0],
[1,0,1,0,0]])
>>> arr1 = numpy.asarray([[1,1,1,0,0],
[0,0,0,0,0],
[1,1,1,0,1],
[0,0,0,0,0],
[1,1,1,0,0]])
>>> obj_fpr(arr1, arr2)
0.0
>>> obj_fpr(arr2, arr1)
0.2
"""
_, _, _, n_obj_reference, mapping = __distinct_binary_object_correspondences(reference, result, connectivity)
return (n_obj_reference - len(mapping)) / float(n_obj_reference)
def obj_tpr(result, reference, connectivity=1):
"""
The true positive rate of distinct binary object detection.
The true positive rates gives a percentage measure of how many distinct binary
objects in the first array also exists in the second array. A partial overlap
(of minimum one voxel) is here considered sufficient.
In cases where two distinct binary object in the first array overlaps with a single
distinct object in the second array, only one is considered to have been detected
successfully.
Parameters
----------
result : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
reference : array_like
Input data containing objects. Can be any type but will be converted
into binary: background where 0, object everywhere else.
connectivity : int
The neighbourhood/connectivity considered when determining what accounts
for a distinct binary object. This value is passed to
`scipy.ndimage.morphology.generate_binary_structure` and should usually be :math:`> 1`.
The decision on the connectivity is important, as it can influence the results
strongly. If in doubt, leave it as it is.
Returns
-------
tpr : float
A percentage measure of how many distinct binary objects in ``result`` also exists
in ``reference``. It has the range :math:`[0, 1]`, where a :math:`1` denotes an ideal score.
Raises
------
RuntimeError
If the reference object is empty.
See also
--------
:func:`obj_fpr`
Notes
-----
This is not a real metric, as it is directed. Whatever array is considered as
reference should be passed second. A perfect score of :math:`1` tells that all distinct
binary objects in the reference array also exist in the result array, but does not
reveal anything about additional binary objects in the result array
(use :func:`obj_fpr` for this).
Examples
--------
>>> arr2 = numpy.asarray([[1,0,0],[1,0,1],[0,0,1]])
>>> arr1 = numpy.asarray([[0,0,1],[1,0,1],[0,0,1]])
>>> arr2
array([[1, 0, 0],
[1, 0, 1],
[0, 0, 1]])
>>> arr1
array([[0, 0, 1],
[1, 0, 1],
[0, 0, 1]])
>>> obj_tpr(arr1, arr2)
1.0
>>> obj_tpr(arr2, arr1)
1.0
Example of directedness:
>>> arr2 = numpy.asarray([1,0,1,0,1])
>>> arr1 = numpy.asarray([1,0,1,0,0])
>>> obj_tpr(arr1, arr2)
0.6666666666666666
>>> obj_tpr(arr2, arr1)
1.0
Examples of multiple overlap treatment:
>>> arr2 = numpy.asarray([1,0,1,0,1,1,1])
>>> arr1 = numpy.asarray([1,1,1,0,1,0,1])
>>> obj_tpr(arr1, arr2)
0.6666666666666666
>>> obj_tpr(arr2, arr1)
0.6666666666666666
>>> arr2 = numpy.asarray([1,0,1,1,1,0,1])
>>> arr1 = numpy.asarray([1,1,1,0,1,1,1])
>>> obj_tpr(arr1, arr2)
0.6666666666666666
>>> obj_tpr(arr2, arr1)
1.0
>>> arr2 = numpy.asarray([[1,0,1,0,0],
[1,0,0,0,0],
[1,0,1,1,1],
[0,0,0,0,0],
[1,0,1,0,0]])
>>> arr1 = numpy.asarray([[1,1,1,0,0],
[0,0,0,0,0],
[1,1,1,0,1],
[0,0,0,0,0],
[1,1,1,0,0]])
>>> obj_tpr(arr1, arr2)
0.8
>>> obj_tpr(arr2, arr1)
1.0
"""
_, _, n_obj_result, _, mapping = __distinct_binary_object_correspondences(reference, result, connectivity)
return len(mapping) / float(n_obj_result)
def __distinct_binary_object_correspondences(reference, result, connectivity=1):
"""
Determines all distinct (where connectivity is defined by the connectivity parameter
passed to scipy's `generate_binary_structure`) binary objects in both of the input
parameters and returns a 1to1 mapping from the labelled objects in reference to the
corresponding (whereas a one-voxel overlap suffices for correspondence) objects in
result.
All stems from the problem, that the relationship is non-surjective many-to-many.
@return (labelmap1, labelmap2, n_lables1, n_labels2, labelmapping2to1)
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
# binary structure
footprint = generate_binary_structure(result.ndim, connectivity)
# label distinct binary objects
labelmap1, n_obj_result = label(result, footprint)
labelmap2, n_obj_reference = label(reference, footprint)
# find all overlaps from labelmap2 to labelmap1; collect one-to-one relationships and store all one-two-many for later processing
slicers = find_objects(labelmap2) # get windows of labelled objects
mapping = dict() # mappings from labels in labelmap2 to corresponding object labels in labelmap1
used_labels = set() # set to collect all already used labels from labelmap2
one_to_many = list() # list to collect all one-to-many mappings
for l1id, slicer in enumerate(slicers): # iterate over object in labelmap2 and their windows
l1id += 1 # labelled objects have ids sarting from 1
bobj = (l1id) == labelmap2[slicer] # find binary object corresponding to the label1 id in the segmentation
l2ids = numpy.unique(labelmap1[slicer][bobj]) # extract all unique object identifiers at the corresponding positions in the reference (i.e. the mapping)
l2ids = l2ids[0 != l2ids] # remove background identifiers (=0)
if 1 == len(l2ids): # one-to-one mapping: if target label not already used, add to final list of object-to-object mappings and mark target label as used
l2id = l2ids[0]
if not l2id in used_labels:
mapping[l1id] = l2id
used_labels.add(l2id)
elif 1 < len(l2ids): # one-to-many mapping: store relationship for later processing
one_to_many.append((l1id, set(l2ids)))
# process one-to-many mappings, always choosing the one with the least labelmap2 correspondences first
while True:
one_to_many = [(l1id, l2ids - used_labels) for l1id, l2ids in one_to_many] # remove already used ids from all sets
one_to_many = [x for x in one_to_many if x[1]] # remove empty sets
one_to_many = sorted(one_to_many, key=lambda x: len(x[1])) # sort by set length
if 0 == len(one_to_many):
break
l2id = one_to_many[0][1].pop() # select an arbitrary target label id from the shortest set
mapping[one_to_many[0][0]] = l2id # add to one-to-one mappings
used_labels.add(l2id) # mark target label as used
one_to_many = one_to_many[1:] # delete the processed set from all sets
return labelmap1, labelmap2, n_obj_result, n_obj_reference, mapping
def __surface_distances(result, reference, voxelspacing=None, connectivity=1):
"""
The distances between the surface voxel of binary objects in result and their
nearest partner surface voxel of a binary object in reference.
"""
result = numpy.atleast_1d(result.astype(numpy.bool))
reference = numpy.atleast_1d(reference.astype(numpy.bool))
if voxelspacing is not None:
voxelspacing = _ni_support._normalize_sequence(voxelspacing, result.ndim)
voxelspacing = numpy.asarray(voxelspacing, dtype=numpy.float64)
if not voxelspacing.flags.contiguous:
voxelspacing = voxelspacing.copy()
# binary structure
footprint = generate_binary_structure(result.ndim, connectivity)
# test for emptiness
if 0 == numpy.count_nonzero(result):
raise RuntimeError('The first supplied array does not contain any binary object.')
if 0 == numpy.count_nonzero(reference):
raise RuntimeError('The second supplied array does not contain any binary object.')
# extract only 1-pixel border line of objects
result_border = result ^ binary_erosion(result, structure=footprint, iterations=1)
reference_border = reference ^ binary_erosion(reference, structure=footprint, iterations=1)
# compute average surface distance
# Note: scipys distance transform is calculated only inside the borders of the
# foreground objects, therefore the input has to be reversed
dt = distance_transform_edt(~reference_border, sampling=voxelspacing)
sds = dt[result_border]
return sds
def __combine_windows(w1, w2):
"""
Joins two windows (defined by tuple of slices) such that their maximum
combined extend is covered by the new returned window.
"""
res = []
for s1, s2 in zip(w1, w2):
res.append(slice(min(s1.start, s2.start), max(s1.stop, s2.stop)))
return tuple(res)
