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author | Vincent Rouvreau <vincent.rouvreau@inria.fr> | 2022-03-08 10:40:01 +0100 |
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committer | Vincent Rouvreau <vincent.rouvreau@inria.fr> | 2022-03-08 10:40:01 +0100 |
commit | 6cb016c0ceff231c001928f641d344fc92c44b73 (patch) | |
tree | 5521dc1396347616a3644f96e6a9f96845c593e1 /src/python/gudhi/wasserstein | |
parent | 69168e8ed24165ab89ea1c57bc21dd994c93dd8e (diff) | |
parent | bbff86f1218fc7bc9976353901aa94cfa54792f6 (diff) |
Merge master and resolve commits
Diffstat (limited to 'src/python/gudhi/wasserstein')
-rw-r--r-- | src/python/gudhi/wasserstein/wasserstein.py | 222 |
1 files changed, 198 insertions, 24 deletions
diff --git a/src/python/gudhi/wasserstein/wasserstein.py b/src/python/gudhi/wasserstein/wasserstein.py index a9d1cdff..dc18806e 100644 --- a/src/python/gudhi/wasserstein/wasserstein.py +++ b/src/python/gudhi/wasserstein/wasserstein.py @@ -9,6 +9,7 @@ import numpy as np import scipy.spatial.distance as sc +import warnings try: import ot @@ -70,6 +71,7 @@ def _perstot_autodiff(X, order, internal_p): ''' return _dist_to_diag(X, internal_p).norms.lp(order) + def _perstot(X, order, internal_p, enable_autodiff): ''' :param X: (n x 2) numpy.array (points of a given diagram). @@ -79,6 +81,9 @@ def _perstot(X, order, internal_p, enable_autodiff): transparent to automatic differentiation. :type enable_autodiff: bool :returns: float, the total persistence of the diagram (that is, its distance to the empty diagram). + + .. note:: + Can be +inf if the diagram has an essential part (points with infinite coordinates). ''' if enable_autodiff: import eagerpy as ep @@ -88,32 +93,163 @@ def _perstot(X, order, internal_p, enable_autodiff): return np.linalg.norm(_dist_to_diag(X, internal_p), ord=order) -def wasserstein_distance(X, Y, matching=False, order=1., internal_p=np.inf, enable_autodiff=False): +def _get_essential_parts(a): ''' - :param X: (n x 2) numpy.array encoding the (finite points of the) first diagram. Must not contain essential points - (i.e. with infinite coordinate). - :param Y: (m x 2) numpy.array encoding the second diagram. - :param matching: if True, computes and returns the optimal matching between X and Y, encoded as - a (n x 2) np.array [...[i,j]...], meaning the i-th point in X is matched to - the j-th point in Y, with the convention (-1) represents the diagonal. - :param order: exponent for Wasserstein; Default value is 1. - :param internal_p: Ground metric on the (upper-half) plane (i.e. norm L^p in R^2); - Default value is `np.inf`. - :param enable_autodiff: If X and Y are torch.tensor or tensorflow.Tensor, make the computation + :param a: (n x 2) numpy.array (point of a diagram) + :returns: five lists of indices (between 0 and len(a)) accounting for the five types of points with infinite + coordinates that can occur in a diagram, namely: + type0 : (-inf, finite) + type1 : (finite, +inf) + type2 : (-inf, +inf) + type3 : (-inf, -inf) + type4 : (+inf, +inf) + .. note:: + For instance, a[_get_essential_parts(a)[0]] returns the points in a of coordinates (-inf, x) for some finite x. + Note also that points with (+inf, -inf) are not handled (points (x,y) in dgm satisfy by assumption (y >= x)). + + Finally, we consider that points with coordinates (-inf,-inf) and (+inf, +inf) belong to the diagonal. + ''' + if len(a): + first_coord_finite = np.isfinite(a[:,0]) + second_coord_finite = np.isfinite(a[:,1]) + first_coord_infinite_positive = (a[:,0] == np.inf) + second_coord_infinite_positive = (a[:,1] == np.inf) + first_coord_infinite_negative = (a[:,0] == -np.inf) + second_coord_infinite_negative = (a[:,1] == -np.inf) + + ess_first_type = np.where(second_coord_finite & first_coord_infinite_negative)[0] # coord (-inf, x) + ess_second_type = np.where(first_coord_finite & second_coord_infinite_positive)[0] # coord (x, +inf) + ess_third_type = np.where(first_coord_infinite_negative & second_coord_infinite_positive)[0] # coord (-inf, +inf) + + ess_fourth_type = np.where(first_coord_infinite_negative & second_coord_infinite_negative)[0] # coord (-inf, -inf) + ess_fifth_type = np.where(first_coord_infinite_positive & second_coord_infinite_positive)[0] # coord (+inf, +inf) + return ess_first_type, ess_second_type, ess_third_type, ess_fourth_type, ess_fifth_type + else: + return [], [], [], [], [] + + +def _cost_and_match_essential_parts(X, Y, idX, idY, order, axis): + ''' + :param X: (n x 2) numpy.array (dgm points) + :param Y: (n x 2) numpy.array (dgm points) + :param idX: indices to consider for this one dimensional OT problem (in X) + :param idY: indices to consider for this one dimensional OT problem (in Y) + :param order: exponent for Wasserstein distance computation + :param axis: must be 0 or 1, correspond to the coordinate which is finite. + :returns: cost (float) and match for points with *one* infinite coordinate. + + .. note:: + Assume idX, idY come when calling _handle_essential_parts, thus have same length. + ''' + u = X[idX, axis] + v = Y[idY, axis] + + cost = np.sum(np.abs(np.sort(u) - np.sort(v))**(order)) # OT cost in 1D + + sortidX = idX[np.argsort(u)] + sortidY = idY[np.argsort(v)] + # We return [i,j] sorted per value + match = list(zip(sortidX, sortidY)) + + return cost, match + + +def _handle_essential_parts(X, Y, order): + ''' + :param X: (n x 2) numpy array, first diagram. + :param Y: (n x 2) numpy array, second diagram. + :order: Wasserstein order for cost computation. + :returns: cost and matching due to essential parts. If cost is +inf, matching will be set to None. + ''' + ess_parts_X = _get_essential_parts(X) + ess_parts_Y = _get_essential_parts(Y) + + # Treats the case of infinite cost (cardinalities of essential parts differ). + for u, v in list(zip(ess_parts_X, ess_parts_Y))[:3]: # ignore types 4 and 5 as they belong to the diagonal + if len(u) != len(v): + return np.inf, None + + # Now we know each essential part has the same number of points in both diagrams. + # Handle type 0 and type 1 essential parts (those with one finite coordinates) + c1, m1 = _cost_and_match_essential_parts(X, Y, ess_parts_X[0], ess_parts_Y[0], axis=1, order=order) + c2, m2 = _cost_and_match_essential_parts(X, Y, ess_parts_X[1], ess_parts_Y[1], axis=0, order=order) + + c = c1 + c2 + m = m1 + m2 + + # Handle type3 (coordinates (-inf,+inf), so we just align points) + m += list(zip(ess_parts_X[2], ess_parts_Y[2])) + + # Handle type 4 and 5, considered as belonging to the diagonal so matched to (-1) with cost 0. + for z in ess_parts_X[3:]: + m += [(u, -1) for u in z] # points in X are matched to -1 + for z in ess_parts_Y[3:]: + m += [(-1, v) for v in z] # -1 is match to points in Y + + return c, np.array(m) + + +def _finite_part(X): + ''' + :param X: (n x 2) numpy array encoding a persistence diagram. + :returns: The finite part of a diagram `X` (points with finite coordinates). + ''' + return X[np.where(np.isfinite(X[:,0]) & np.isfinite(X[:,1]))] + + +def _warn_infty(matching): + ''' + Handle essential parts with different cardinalities. Warn the user about cost being infinite and (if + `matching=True`) about the returned matching being `None`. + ''' + if matching: + warnings.warn('Cardinality of essential parts differs. Distance (cost) is +inf, and the returned matching is None.') + return np.inf, None + else: + warnings.warn('Cardinality of essential parts differs. Distance (cost) is +inf.') + return np.inf + + +def wasserstein_distance(X, Y, matching=False, order=1., internal_p=np.inf, enable_autodiff=False, + keep_essential_parts=True): + ''' + Compute the Wasserstein distance between persistence diagram using Python Optimal Transport backend. + Diagrams can contain points with infinity coordinates (essential parts). + Points with (-inf,-inf) and (+inf,+inf) coordinates are considered as belonging to the diagonal. + If the distance between two diagrams is +inf (which happens if the cardinalities of essential + parts differ) and optimal matching is required, it will be set to ``None``. + + :param X: The first diagram. + :type X: n x 2 numpy.array + :param Y: The second diagram. + :type Y: m x 2 numpy.array + :param matching: if ``True``, computes and returns the optimal matching between X and Y, encoded as + a (n x 2) np.array [...[i,j]...], meaning the i-th point in X is matched to + the j-th point in Y, with the convention that (-1) represents the diagonal. + :param order: Wasserstein exponent q (1 <= q < infinity). + :type order: float + :param internal_p: Ground metric on the (upper-half) plane (i.e. norm L^p in R^2). + :type internal_p: float + :param enable_autodiff: If X and Y are ``torch.tensor`` or ``tensorflow.Tensor``, make the computation transparent to automatic differentiation. This requires the package EagerPy and is currently incompatible - with `matching=True`. + with ``matching=True`` and with ``keep_essential_parts=True``. - .. note:: This considers the function defined on the coordinates of the off-diagonal points of X and Y + .. note:: This considers the function defined on the coordinates of the off-diagonal finite points of X and Y and lets the various frameworks compute its gradient. It never pulls new points from the diagonal. :type enable_autodiff: bool - :returns: the Wasserstein distance of order q (1 <= q < infinity) between persistence diagrams with + :param keep_essential_parts: If ``False``, only considers the finite points in the diagrams. + Otherwise, include essential parts in cost and matching computation. + :type keep_essential_parts: bool + :returns: The Wasserstein distance of order q (1 <= q < infinity) between persistence diagrams with respect to the internal_p-norm as ground metric. If matching is set to True, also returns the optimal matching between X and Y. + If cost is +inf, any matching is optimal and thus it returns `None` instead. ''' + + # First step: handle empty diagrams n = len(X) m = len(Y) - # handle empty diagrams if n == 0: if m == 0: if not matching: @@ -122,16 +258,45 @@ def wasserstein_distance(X, Y, matching=False, order=1., internal_p=np.inf, enab else: return 0., np.array([]) else: - if not matching: - return _perstot(Y, order, internal_p, enable_autodiff) + cost = _perstot(Y, order, internal_p, enable_autodiff) + if cost == np.inf: + return _warn_infty(matching) else: - return _perstot(Y, order, internal_p, enable_autodiff), np.array([[-1, j] for j in range(m)]) + if not matching: + return cost + else: + return cost, np.array([[-1, j] for j in range(m)]) elif m == 0: - if not matching: - return _perstot(X, order, internal_p, enable_autodiff) + cost = _perstot(X, order, internal_p, enable_autodiff) + if cost == np.inf: + return _warn_infty(matching) else: - return _perstot(X, order, internal_p, enable_autodiff), np.array([[i, -1] for i in range(n)]) + if not matching: + return cost + else: + return cost, np.array([[i, -1] for i in range(n)]) + + # Check essential part and enable autodiff together + if enable_autodiff and keep_essential_parts: + warnings.warn('''enable_autodiff=True and keep_essential_parts=True are incompatible together. + keep_essential_parts is set to False: only points with finite coordinates are considered + in the following. + ''') + keep_essential_parts = False + + # Second step: handle essential parts if needed. + if keep_essential_parts: + essential_cost, essential_matching = _handle_essential_parts(X, Y, order=order) + if (essential_cost == np.inf): + return _warn_infty(matching) # Tells the user that cost is infty and matching (if True) is None. + # avoid computing transport cost between the finite parts if essential parts + # cardinalities do not match (saves time) + else: + essential_cost = 0 + essential_matching = None + + # Now the standard pipeline for finite parts if enable_autodiff: import eagerpy as ep @@ -139,6 +304,12 @@ def wasserstein_distance(X, Y, matching=False, order=1., internal_p=np.inf, enab Y_orig = ep.astensor(Y) X = X_orig.numpy() Y = Y_orig.numpy() + + # Extract finite points of the diagrams. + X, Y = _finite_part(X), _finite_part(Y) + n = len(X) + m = len(Y) + M = _build_dist_matrix(X, Y, order=order, internal_p=internal_p) a = np.ones(n+1) # weight vector of the input diagram. Uniform here. a[-1] = m @@ -154,7 +325,10 @@ def wasserstein_distance(X, Y, matching=False, order=1., internal_p=np.inf, enab # Now we turn to -1 points encoding the diagonal match[:,0][match[:,0] >= n] = -1 match[:,1][match[:,1] >= m] = -1 - return ot_cost ** (1./order) , match + # Finally incorporate the essential part matching + if essential_matching is not None: + match = np.concatenate([match, essential_matching]) if essential_matching.size else match + return (ot_cost + essential_cost) ** (1./order) , match if enable_autodiff: P = ot.emd(a=a, b=b, M=M, numItermax=2000000) @@ -173,9 +347,9 @@ def wasserstein_distance(X, Y, matching=False, order=1., internal_p=np.inf, enab return ep.concatenate(dists).norms.lp(order).raw # We can also concatenate the 3 vectors to compute just one norm. - # Comptuation of the otcost using the ot.emd2 library. + # Comptuation of the ot cost using the ot.emd2 library. # Note: it is the Wasserstein distance to the power q. # The default numItermax=100000 is not sufficient for some examples with 5000 points, what is a good value? ot_cost = ot.emd2(a, b, M, numItermax=2000000) - return ot_cost ** (1./order) + return (ot_cost + essential_cost) ** (1./order) |