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"""

Benchmark for approximate nearest neighbor search using

locality sensitive hashing forest.

There are two types of benchmarks.

First, accuracy of LSHForest queries are measured for various

hyper-parameters and index sizes.

Second, speed up of LSHForest queries compared to brute force

method in exact nearest neighbors is measures for the

aforementioned settings. In general, speed up is increasing as

the index size grows.

"""

from __future__ import division

import numpy as np

from tempfile import gettempdir

from time import time

from sklearn.neighbors import NearestNeighbors

from sklearn.neighbors.approximate import LSHForest

from sklearn.datasets import make_blobs

from sklearn.externals.joblib import Memory

m = Memory(cachedir=gettempdir())

@m.cache()

def make_data(n_samples, n_features, n_queries, random_state=0):

"""Create index and query data."""

print('Generating random blob-ish data')

X, _ = make_blobs(n_samples=n_samples + n_queries,

n_features=n_features, centers=100,

shuffle=True, random_state=random_state)

# Keep the last samples as held out query vectors: note since we used

# shuffle=True we have ensured that index and query vectors are

# samples from the same distribution (a mixture of 100 gaussians in this

# case)

return X[:n_samples], X[n_samples:]

def calc_exact_neighbors(X, queries, n_queries, n_neighbors):

"""Measures average times for exact neighbor queries."""

print ('Building NearestNeighbors for %d samples in %d dimensions' %

(X.shape[0], X.shape[1]))

nbrs = NearestNeighbors(algorithm='brute', metric='cosine').fit(X)

average_time = 0

t0 = time()

neighbors = nbrs.kneighbors(queries, n_neighbors=n_neighbors,

return_distance=False)

average_time = (time() - t0) / n_queries

return neighbors, average_time

def calc_accuracy(X, queries, n_queries, n_neighbors, exact_neighbors,

average_time_exact, **lshf_params):

"""Calculates accuracy and the speed up of LSHForest."""

print('Building LSHForest for %d samples in %d dimensions' %

(X.shape[0], X.shape[1]))

lshf = LSHForest(**lshf_params)

t0 = time()

lshf.fit(X)

lshf_build_time = time() - t0

print('Done in %0.3fs' % lshf_build_time)

accuracy = 0

t0 = time()

approx_neighbors = lshf.kneighbors(queries, n_neighbors=n_neighbors,

return_distance=False)

average_time_approx = (time() - t0) / n_queries

for i in range(len(queries)):

accuracy += np.in1d(approx_neighbors[i], exact_neighbors[i]).mean()

accuracy /= n_queries

speed_up = average_time_exact / average_time_approx

print('Average time for lshf neighbor queries: %0.3fs' %

average_time_approx)

print ('Average time for exact neighbor queries: %0.3fs' %

average_time_exact)

print ('Average Accuracy : %0.2f' % accuracy)

print ('Speed up: %0.1fx' % speed_up)

return speed_up, accuracy

if __name__ == '__main__':

import matplotlib.pyplot as plt

# Initialize index sizes

n_samples = [int(1e3), int(1e4), int(1e5), int(1e6)]

n_features = int(1e2)

n_queries = 100

n_neighbors = 10

X_index, X_query = make_data(np.max(n_samples), n_features, n_queries,

random_state=0)

params_list = [{'n_estimators': 3, 'n_candidates': 50},

{'n_estimators': 5, 'n_candidates': 70},

{'n_estimators': 10, 'n_candidates': 100}]

accuracies = np.zeros((len(n_samples), len(params_list)), dtype=float)

speed_ups = np.zeros((len(n_samples), len(params_list)), dtype=float)

for i, sample_size in enumerate(n_samples):

print ('==========================================================')

print ('Sample size: %i' % sample_size)

print ('------------------------')

exact_neighbors, average_time_exact = calc_exact_neighbors(

X_index[:sample_size], X_query, n_queries, n_neighbors)

for j, params in enumerate(params_list):

print ('LSHF parameters: n_estimators = %i, n_candidates = %i' %

(params['n_estimators'], params['n_candidates']))

speed_ups[i, j], accuracies[i, j] = calc_accuracy(

X_index[:sample_size], X_query, n_queries, n_neighbors,

exact_neighbors, average_time_exact, random_state=0, **params)

print ('')

print ('==========================================================')

# Set labels for LSHForest parameters

colors = ['c', 'm', 'y']

p1 = plt.Rectangle((0, 0), 0.1, 0.1, fc=colors[0])

p2 = plt.Rectangle((0, 0), 0.1, 0.1, fc=colors[1])

p3 = plt.Rectangle((0, 0), 0.1, 0.1, fc=colors[2])

labels = ['n_estimators=' + str(params_list[0]['n_estimators']) +

', n_candidates=' + str(params_list[0]['n_candidates']),

'n_estimators=' + str(params_list[1]['n_estimators']) +

', n_candidates=' + str(params_list[1]['n_candidates']),

'n_estimators=' + str(params_list[2]['n_estimators']) +

', n_candidates=' + str(params_list[2]['n_candidates'])]

# Plot precision

plt.figure()

plt.legend((p1, p2, p3), (labels[0], labels[1], labels[2]),

loc='upper left')

for i in range(len(params_list)):

plt.scatter(n_samples, accuracies[:, i], c=colors[i])

plt.plot(n_samples, accuracies[:, i], c=colors[i])

plt.ylim([0, 1.3])

plt.xlim(np.min(n_samples), np.max(n_samples))

plt.semilogx()

plt.ylabel("Precision@10")

plt.xlabel("Index size")

plt.grid(which='both')

plt.title("Precision of first 10 neighbors with index size")

# Plot speed up

plt.figure()

plt.legend((p1, p2, p3), (labels[0], labels[1], labels[2]),

loc='upper left')

for i in range(len(params_list)):

plt.scatter(n_samples, speed_ups[:, i], c=colors[i])

plt.plot(n_samples, speed_ups[:, i], c=colors[i])

plt.ylim(0, np.max(speed_ups))

plt.xlim(np.min(n_samples), np.max(n_samples))

plt.semilogx()

plt.ylabel("Speed up")

plt.xlabel("Index size")

plt.grid(which='both')

plt.title("Relationship between Speed up and index size")

plt.show()