# Fast calculation of Pareto front in Python

I have a set of points in a 3D space, from which I need to find the Pareto frontier. Speed of execution is very important here, and time increases very fast as I add points to test.

The set of points looks like this:

``````[[0.3296170319979843, 0.0, 0.44472108843537406], [0.3296170319979843,0.0, 0.44472108843537406], [0.32920760896951373, 0.0, 0.4440408163265306], [0.32920760896951373, 0.0, 0.4440408163265306], [0.33815192743764166, 0.0, 0.44356462585034007]]
``````

Right now, I'm using this algorithm:

``````def dominates(row, candidateRow):
return sum([row[x] >= candidateRow[x] for x in range(len(row))]) == len(row)

def simple_cull(inputPoints, dominates):
paretoPoints = set()
candidateRowNr = 0
dominatedPoints = set()
while True:
candidateRow = inputPoints[candidateRowNr]
inputPoints.remove(candidateRow)
rowNr = 0
nonDominated = True
while len(inputPoints) != 0 and rowNr < len(inputPoints):
row = inputPoints[rowNr]
if dominates(candidateRow, row):
# If it is worse on all features remove the row from the array
inputPoints.remove(row)
elif dominates(row, candidateRow):
nonDominated = False
rowNr += 1
else:
rowNr += 1

if nonDominated:
# add the non-dominated point to the Pareto frontier

if len(inputPoints) == 0:
break
return paretoPoints, dominatedPoints
``````

What's the fastest way to find the set of non-dominated solutions in an ensemble of solutions? Or, in short, can Python do better than this algorithm?

If you're worried about actual speed, you definitely want to use numpy (as the clever algorithmic tweaks probably have way less effect than the gains to be had from using array operations). Here are three solutions that all compute the same function. The `is_pareto_efficient_dumb` solution is slower in most situations but becomes faster as the number of costs increases, the `is_pareto_efficient_simple` solution is much more efficient than the dumb solution for many points, and the final `is_pareto_efficient` function is less readable but the fastest (so all are Pareto Efficient!).

``````import numpy as np

# Very slow for many datapoints.  Fastest for many costs, most readable
def is_pareto_efficient_dumb(costs):
"""
Find the pareto-efficient points
:param costs: An (n_points, n_costs) array
:return: A (n_points, ) boolean array, indicating whether each point is Pareto efficient
"""
is_efficient = np.ones(costs.shape, dtype = bool)
for i, c in enumerate(costs):
is_efficient[i] = np.all(np.any(costs[:i]>c, axis=1)) and np.all(np.any(costs[i+1:]>c, axis=1))
return is_efficient

# Fairly fast for many datapoints, less fast for many costs, somewhat readable
def is_pareto_efficient_simple(costs):
"""
Find the pareto-efficient points
:param costs: An (n_points, n_costs) array
:return: A (n_points, ) boolean array, indicating whether each point is Pareto efficient
"""
is_efficient = np.ones(costs.shape, dtype = bool)
for i, c in enumerate(costs):
if is_efficient[i]:
is_efficient[is_efficient] = np.any(costs[is_efficient]<c, axis=1)  # Keep any point with a lower cost
is_efficient[i] = True  # And keep self
return is_efficient

# Faster than is_pareto_efficient_simple, but less readable.
"""
Find the pareto-efficient points
:param costs: An (n_points, n_costs) array
:return: An array of indices of pareto-efficient points.
If return_mask is True, this will be an (n_points, ) boolean array
Otherwise it will be a (n_efficient_points, ) integer array of indices.
"""
is_efficient = np.arange(costs.shape)
n_points = costs.shape
next_point_index = 0  # Next index in the is_efficient array to search for
while next_point_index<len(costs):
is_efficient = is_efficient[nondominated_point_mask]  # Remove dominated points
is_efficient_mask = np.zeros(n_points, dtype = bool)
else:
return is_efficient
``````

Profiling tests (using points drawn from a Normal distribution):

With 10,000 samples, 2 costs:

``````is_pareto_efficient_dumb: Elapsed time is 1.586s
is_pareto_efficient_simple: Elapsed time is 0.009653s
is_pareto_efficient: Elapsed time is 0.005479s
``````

With 1,000,000 samples, 2 costs:

``````is_pareto_efficient_dumb: Really, really, slow
is_pareto_efficient_simple: Elapsed time is 1.174s
is_pareto_efficient: Elapsed time is 0.4033s
``````

With 10,000 samples, 15 costs:

``````is_pareto_efficient_dumb: Elapsed time is 4.019s
is_pareto_efficient_simple: Elapsed time is 6.466s
is_pareto_efficient: Elapsed time is 6.41s
``````

Note that if efficiency is a concern you can gain maybe a further 2x or so speedup by reordering your data beforehand, see here.

• Wow, I missed it, thank you Peter! I"m not quite sure I get the cost array though, could you provide a short example? Thanks once again, this looks fantastic. Jan 2, 2017 at 18:37
• Cost array is just a 2-d array where cost[i, j] is the j'th cost of the i'th data point. I think it's the same as your inputPoints array. You can see the tests here, which demonstrate its use. Jan 3, 2017 at 10:46
• I tested it with a simple example and the first two functions do not return the pareto front. The example: `numpy.array([[1,2], [3,4], [2,1], [1,1]])` It returns the following: `[ True False True True]` But it should return by the definition of pareto front this: `[ False False False True]` Dec 16, 2018 at 23:34
• A fix for the def is_pareto_efficient(costs): would look like this (replace the mentioned lines): `is_efficient[is_efficient] = np.any(costs[is_efficient]<c, axis=1) # Remove dominated points` `is_efficient[i] = True` Dec 16, 2018 at 23:49
• Can you share the reference to scientific papers about these algorithms?
– w4bo
Dec 19, 2020 at 15:03

### Updated Aug 2019

Here is another simple implementation that is pretty fast for modest dimensions. Input points are assumed to be unique.

``````def keep_efficient(pts):
'returns Pareto efficient row subset of pts'
# sort points by decreasing sum of coordinates
pts = pts[pts.sum(1).argsort()[::-1]]
# initialize a boolean mask for undominated points
# to avoid creating copies each iteration
undominated = np.ones(pts.shape, dtype=bool)
for i in range(pts.shape):
# process each point in turn
n = pts.shape
if i >= n:
break
# find all points not dominated by i
# since points are sorted by coordinate sum
# i cannot dominate any points in 1,...,i-1
undominated[i+1:n] = (pts[i+1:] >= pts[i]).any(1)
# keep points undominated so far
pts = pts[undominated[:n]]
return pts
``````

We start by sorting points according to the sum of coordinates. This is useful because

• For many distributions of data, a point with a largest coordinate sum will dominate a large number of points.
• If point `x` has a larger coordinate sum than point `y`, then `y` cannot dominate `x`.

Here are some benchmarks relative to Peter's answer, using `np.random.randn`.

``````N=10000 d=2

keep_efficient
1.31 ms ± 11.6 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
is_pareto_efficient
6.51 ms ± 23.9 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

N=10000 d=3

keep_efficient
2.3 ms ± 13.3 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
is_pareto_efficient
16.4 ms ± 156 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

N=10000 d=4

keep_efficient
4.37 ms ± 38.4 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
is_pareto_efficient
21.1 ms ± 115 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)

N=10000 d=5

keep_efficient
15.1 ms ± 491 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
is_pareto_efficient
110 ms ± 1.01 ms per loop (mean ± std. dev. of 7 runs, 10 loops each)

N=10000 d=6

keep_efficient
40.1 ms ± 211 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
is_pareto_efficient
279 ms ± 2.54 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

N=10000 d=15

keep_efficient
3.92 s ± 125 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
is_pareto_efficient
5.88 s ± 74.3 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)
``````

### Convex Hull Heuristic

I ended up looking at this problem recently and found a useful heuristic that works well if there are many points distributed independently and dimensions are few.

The idea is to compute the convex hull of points. With few dimensions and independently distributed points, the number of vertices of the convex hull will be small. Intuitively, we can expect some vertices of the convex hull to dominate many of the original points. Moreover, if a point in a convex hull is not dominated by any other point in the convex hull, then it is also not dominated by any point in the original set.

This gives a simple iterative algorithm. We repeatedly

1. Compute the convex hull.
2. Save Pareto undominated points from the convex hull.
3. Filter the points to remove those dominated by elements of the convex hull.

I add a few benchmarks for dimension 3. It seems that for some distribution of points this approach yields better asymptotics.

``````import numpy as np
from scipy import spatial
from functools import reduce

# test points
pts = np.random.rand(10_000_000, 3)

def filter_(pts, pt):
"""
Get all points in pts that are not Pareto dominated by the point pt
"""
weakly_worse   = (pts <= pt).all(axis=-1)
strictly_worse = (pts < pt).any(axis=-1)
return pts[~(weakly_worse & strictly_worse)]

def get_pareto_undominated_by(pts1, pts2=None):
"""
Return all points in pts1 that are not Pareto dominated
by any points in pts2
"""
if pts2 is None:
pts2 = pts1
return reduce(filter_, pts2, pts1)

def get_pareto_frontier(pts):
"""
Iteratively filter points based on the convex hull heuristic
"""
pareto_groups = []

# loop while there are points remaining
while pts.shape:
# brute force if there are few points:
if pts.shape < 10:
pareto_groups.append(get_pareto_undominated_by(pts))
break

# compute vertices of the convex hull
hull_vertices = spatial.ConvexHull(pts).vertices

# get corresponding points
hull_pts = pts[hull_vertices]

# get points in pts that are not convex hull vertices

# get points in the convex hull that are on the Pareto frontier
pareto   = get_pareto_undominated_by(hull_pts)
pareto_groups.append(pareto)

# filter remaining points to keep those not dominated by
# Pareto points of the convex hull
pts = get_pareto_undominated_by(pts, pareto)

return np.vstack(pareto_groups)

# --------------------------------------------------------------------------------
# previous solutions
# --------------------------------------------------------------------------------

def is_pareto_efficient_dumb(costs):
"""
:param costs: An (n_points, n_costs) array
:return: A (n_points, ) boolean array, indicating whether each point is Pareto efficient
"""
is_efficient = np.ones(costs.shape, dtype = bool)
for i, c in enumerate(costs):
is_efficient[i] = np.all(np.any(costs>=c, axis=1))
return is_efficient

def is_pareto_efficient(costs):
"""
:param costs: An (n_points, n_costs) array
:return: A (n_points, ) boolean array, indicating whether each point is Pareto efficient
"""
is_efficient = np.ones(costs.shape, dtype = bool)
for i, c in enumerate(costs):
if is_efficient[i]:
is_efficient[is_efficient] = np.any(costs[is_efficient]<=c, axis=1)  # Remove dominated points
return is_efficient

def dominates(row, rowCandidate):
return all(r >= rc for r, rc in zip(row, rowCandidate))

def cull(pts, dominates):
dominated = []
cleared = []
remaining = pts
while remaining:
candidate = remaining
new_remaining = []
for other in remaining[1:]:
[new_remaining, dominated][dominates(candidate, other)].append(other)
if not any(dominates(other, candidate) for other in new_remaining):
cleared.append(candidate)
else:
dominated.append(candidate)
remaining = new_remaining
return cleared, dominated

# --------------------------------------------------------------------------------
# benchmarking
# --------------------------------------------------------------------------------

# to accomodate the original non-numpy solution
pts_list = [list(pt) for pt in pts]

import timeit

# print('Old non-numpy solution:s\t{}'.format(
# timeit.timeit('cull(pts_list, dominates)', number=3, globals=globals())))

print('Numpy solution:\t{}'.format(
timeit.timeit('is_pareto_efficient(pts)', number=3, globals=globals())))

print('Convex hull heuristic:\t{}'.format(
timeit.timeit('get_pareto_frontier(pts)', number=3, globals=globals())))
``````

### Results

``````# >>= python temp.py # 1,000 points
# Old non-numpy solution:      0.0316428339574486
# Numpy solution:              0.005961259012110531
# Convex hull heuristic:       0.012369581032544374
# >>= python temp.py # 1,000,000 points
# Old non-numpy solution:      70.67529802105855
# Numpy solution:              5.398462114972062
# Convex hull heuristic:       1.5286884519737214
# >>= python temp.py # 10,000,000 points
# Numpy solution:              98.03680767398328
# Convex hull heuristic:       10.203076395904645
``````

### Original Post

I took a shot at rewriting the same algorithm with a couple of tweaks. I think most of your problems come from `inputPoints.remove(row)`. This requires searching through the list of points; removing by index would be much more efficient. I also modified the `dominates` function to avoid some redundant comparisons. This could be handy in a higher dimension.

``````def dominates(row, rowCandidate):
return all(r >= rc for r, rc in zip(row, rowCandidate))

def cull(pts, dominates):
dominated = []
cleared = []
remaining = pts
while remaining:
candidate = remaining
new_remaining = []
for other in remaining[1:]:
[new_remaining, dominated][dominates(candidate, other)].append(other)
if not any(dominates(other, candidate) for other in new_remaining):
cleared.append(candidate)
else:
dominated.append(candidate)
remaining = new_remaining
return cleared, dominated
``````
• Thanks, I'm trying right now. Any idea how it would compare to the first answer here: stackoverflow.com/questions/21294829/… ? Sep 26, 2015 at 19:53
• Thank you for this answer. It would also be nice to know how to choose the best point in the set of points returned as the Pareto frontier. Also, there may be some objectives that need to be minimized and some need to be maximized and some need to kept constant.
– Nav
Oct 2, 2019 at 9:15
• @Nav I am not sure I follow your suggestion entirely. For every point in the Pareto frontier it is possible to write down an objective function s.t. that point is "the best". Are you thinking about multi-objective optimization? This is not something I had in mind for this answer. Oct 2, 2019 at 10:25
• Yes; multiobjective optimization. I eventually realized I could just use your function and then calculate the centroid of the Pareto optimal points using K-Means to find the approx. "best" point. Also, since `min(f(x)) = - max(-f(x))`, I could use your function unchanged and simply negate the columns of numbers that I want to minimize.
– Nav
Oct 3, 2019 at 2:25
• The code from Update Aug 2019 looks to be not working properly - the returned set is not the efficient frontier. For example for this set (gist.github.com/vfilimonov/4e368a7a6235ae2aff8e9c47a569e974) many points from pareto frontier are missing Mar 17, 2021 at 13:47

Peter, nice response.

I just wanted to generalise for those who want to choose between maximisation to your default of minimisation. It's a trivial fix, but nice to document here:

``````def is_pareto(costs, maximise=False):
"""
:param costs: An (n_points, n_costs) array
:maximise: boolean. True for maximising, False for minimising
:return: A (n_points, ) boolean array, indicating whether each point is Pareto efficient
"""
is_efficient = np.ones(costs.shape, dtype = bool)
for i, c in enumerate(costs):
if is_efficient[i]:
if maximise:
is_efficient[is_efficient] = np.any(costs[is_efficient]>=c, axis=1)  # Remove dominated points
else:
is_efficient[is_efficient] = np.any(costs[is_efficient]<=c, axis=1)  # Remove dominated points
return is_efficient
``````

The definition of `dominates` is incorrect. A dominates B if and only if it is better than or equal to B on all dimensions, and strictly better on at least one dimension.

I might be a little late here but I experimented with the proposed solutions and it seems that they are failing to return all the Pareto points. I have made a recursive implementation (which is significantly faster) to find the Pareto-front and you can find it at https://github.com/Ragheb2464/preto-front

• Please provide a counter-example Aug 19, 2021 at 7:38
• Nice! Your solution worked for me, all the others didn't (i don't know how to retrieve the costs array) Oct 12, 2021 at 11:31

Correcting an error found in a previous post, here is a new version of the keep_efficient function.

``````def keep_efficient(pts):
'returns Pareto efficient row subset of pts'
# sort points by decreasing sum of coordinates
pts = pts[pts.sum(1).argsort()[::-1]]
# initialize a boolean mask for undominated points
# to avoid creating copies each iteration
undominated = np.ones(pts.shape, dtype=bool)
for i in range(pts.shape):
# process each point in turn
n = pts.shape
if i >= n:
break
# find all points not dominated by i
# since points are sorted by coordinate sum
# i cannot dominate any points in 1,...,i-1
undominated[i+1:n] = (pts[i+1:] >= pts[i]).any(1)
# keep points undominated so far
pts = pts[undominated[:n]]
undominated = np.array([True]*len(pts))

return pts
``````

(Note that the error in the previous post was that the function keep_efficient(pts) returned a wrong Pareto front with inputs: pts = [[5,5],[4,3], [0,6]]. Before the edit, the result was [5,5] while the expected result is [[5 5], [0 6]]. The fix was to add the last line of the for loop: undominated = np.array([True]*len(pts)))

Just to be clear for the example above, the function to get the Pareto-front is slightly different then in the code above and should include only a < not a <= looking like this:

``````def is_pareto(costs):
is_efficient = np.ones(costs.shape, dtype=bool)

for i, c in enumerate(is_efficient):
if is_efficient[i]:
is_efficient[is_efficient] = np.any(costs[is_efficient]<c, axis=1)

return is_efficient
``````

Disclaimer: This is only partial correct because domination itself is defined as <= for all and only < for at least one. But for most cases it should be sufficient