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bench_gpu_1bn.py
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bench_gpu_1bn.py
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#! /usr/bin/env python2
# Copyright (c) Facebook, Inc. and its affiliates.
#
# This source code is licensed under the MIT license found in the
# LICENSE file in the root directory of this source tree.
from __future__ import print_function
import numpy as np
import time
import os
import sys
import faiss
import re
from multiprocessing.dummy import Pool as ThreadPool
from datasets import ivecs_read
####################################################################
# Parse command line
####################################################################
def usage():
print("""
Usage: bench_gpu_1bn.py dataset indextype [options]
dataset: set of vectors to operate on.
Supported: SIFT1M, SIFT2M, ..., SIFT1000M or Deep1B
indextype: any index type supported by index_factory that runs on GPU.
General options
-ngpu ngpu nb of GPUs to use (default = all)
-tempmem N use N bytes of temporary GPU memory
-nocache do not read or write intermediate files
-float16 use 16-bit floats on the GPU side
Add options
-abs N split adds in blocks of no more than N vectors
-max_add N copy sharded dataset to CPU each max_add additions
(to avoid memory overflows with geometric reallocations)
-altadd Alternative add function, where the index is not stored
on GPU during add. Slightly faster for big datasets on
slow GPUs
Search options
-R R: nb of replicas of the same dataset (the dataset
will be copied across ngpu/R, default R=1)
-noptables do not use precomputed tables in IVFPQ.
-qbs N split queries in blocks of no more than N vectors
-nnn N search N neighbors for each query
-nprobe 4,16,64 try this number of probes
-knngraph instead of the standard setup for the dataset,
compute a k-nn graph with nnn neighbors per element
-oI xx%d.npy output the search result indices to this numpy file,
%d will be replaced with the nprobe
-oD xx%d.npy output the search result distances to this file
""", file=sys.stderr)
sys.exit(1)
# default values
dbname = None
index_key = None
ngpu = faiss.get_num_gpus()
replicas = 1 # nb of replicas of sharded dataset
add_batch_size = 32768
query_batch_size = 16384
nprobes = [1 << l for l in range(9)]
knngraph = False
use_precomputed_tables = True
tempmem = -1 # if -1, use system default
max_add = -1
use_float16 = False
use_cache = True
nnn = 10
altadd = False
I_fname = None
D_fname = None
args = sys.argv[1:]
while args:
a = args.pop(0)
if a == '-h': usage()
elif a == '-ngpu': ngpu = int(args.pop(0))
elif a == '-R': replicas = int(args.pop(0))
elif a == '-noptables': use_precomputed_tables = False
elif a == '-abs': add_batch_size = int(args.pop(0))
elif a == '-qbs': query_batch_size = int(args.pop(0))
elif a == '-nnn': nnn = int(args.pop(0))
elif a == '-tempmem': tempmem = int(args.pop(0))
elif a == '-nocache': use_cache = False
elif a == '-knngraph': knngraph = True
elif a == '-altadd': altadd = True
elif a == '-float16': use_float16 = True
elif a == '-nprobe': nprobes = [int(x) for x in args.pop(0).split(',')]
elif a == '-max_add': max_add = int(args.pop(0))
elif not dbname: dbname = a
elif not index_key: index_key = a
else:
print("argument %s unknown" % a, file=sys.stderr)
sys.exit(1)
cacheroot = '/tmp/bench_gpu_1bn'
if not os.path.isdir(cacheroot):
print("%s does not exist, creating it" % cacheroot)
os.mkdir(cacheroot)
#################################################################
# Small Utility Functions
#################################################################
# we mem-map the biggest files to avoid having them in memory all at
# once
def mmap_fvecs(fname):
x = np.memmap(fname, dtype='int32', mode='r')
d = x[0]
return x.view('float32').reshape(-1, d + 1)[:, 1:]
def mmap_bvecs(fname):
x = np.memmap(fname, dtype='uint8', mode='r')
d = x[:4].view('int32')[0]
return x.reshape(-1, d + 4)[:, 4:]
def rate_limited_imap(f, l):
"""A threaded imap that does not produce elements faster than they
are consumed"""
pool = ThreadPool(1)
res = None
for i in l:
res_next = pool.apply_async(f, (i, ))
if res:
yield res.get()
res = res_next
yield res.get()
class IdentPreproc:
"""a pre-processor is either a faiss.VectorTransform or an IndentPreproc"""
def __init__(self, d):
self.d_in = self.d_out = d
def apply_py(self, x):
return x
def sanitize(x):
""" convert array to a c-contiguous float array """
return np.ascontiguousarray(x.astype('float32'))
def dataset_iterator(x, preproc, bs):
""" iterate over the lines of x in blocks of size bs"""
nb = x.shape[0]
block_ranges = [(i0, min(nb, i0 + bs))
for i0 in range(0, nb, bs)]
def prepare_block(i01):
i0, i1 = i01
xb = sanitize(x[i0:i1])
return i0, preproc.apply_py(xb)
return rate_limited_imap(prepare_block, block_ranges)
def eval_intersection_measure(gt_I, I):
""" measure intersection measure (used for knngraph)"""
inter = 0
rank = I.shape[1]
assert gt_I.shape[1] >= rank
for q in range(nq_gt):
inter += faiss.ranklist_intersection_size(
rank, faiss.swig_ptr(gt_I[q, :]),
rank, faiss.swig_ptr(I[q, :].astype('int64')))
return inter / float(rank * nq_gt)
#################################################################
# Prepare dataset
#################################################################
print("Preparing dataset", dbname)
if dbname.startswith('SIFT'):
# SIFT1M to SIFT1000M
dbsize = int(dbname[4:-1])
xb = mmap_bvecs('bigann/bigann_base.bvecs')
xq = mmap_bvecs('bigann/bigann_query.bvecs')
xt = mmap_bvecs('bigann/bigann_learn.bvecs')
# trim xb to correct size
xb = xb[:dbsize * 1000 * 1000]
gt_I = ivecs_read('bigann/gnd/idx_%dM.ivecs' % dbsize)
elif dbname == 'Deep1B':
xb = mmap_fvecs('deep1b/base.fvecs')
xq = mmap_fvecs('deep1b/deep1B_queries.fvecs')
xt = mmap_fvecs('deep1b/learn.fvecs')
# deep1B's train is is outrageously big
xt = xt[:10 * 1000 * 1000]
gt_I = ivecs_read('deep1b/deep1B_groundtruth.ivecs')
else:
print('unknown dataset', dbname, file=sys.stderr)
sys.exit(1)
if knngraph:
# convert to knn-graph dataset
xq = xb
xt = xb
# we compute the ground-truth on this number of queries for validation
nq_gt = 10000
gt_sl = 100
# ground truth will be computed below
gt_I = None
print("sizes: B %s Q %s T %s gt %s" % (
xb.shape, xq.shape, xt.shape,
gt_I.shape if gt_I is not None else None))
#################################################################
# Parse index_key and set cache files
#
# The index_key is a valid factory key that would work, but we
# decompose the training to do it faster
#################################################################
pat = re.compile('(OPQ[0-9]+(_[0-9]+)?,|PCAR[0-9]+,)?' +
'(IVF[0-9]+),' +
'(PQ[0-9]+|Flat)')
matchobject = pat.match(index_key)
assert matchobject, 'could not parse ' + index_key
mog = matchobject.groups()
preproc_str = mog[0]
ivf_str = mog[2]
pqflat_str = mog[3]
ncent = int(ivf_str[3:])
prefix = ''
if knngraph:
gt_cachefile = '%s/BK_gt_%s.npy' % (cacheroot, dbname)
prefix = 'BK_'
# files must be kept distinct because the training set is not the
# same for the knngraph
if preproc_str:
preproc_cachefile = '%s/%spreproc_%s_%s.vectrans' % (
cacheroot, prefix, dbname, preproc_str[:-1])
else:
preproc_cachefile = None
preproc_str = ''
cent_cachefile = '%s/%scent_%s_%s%s.npy' % (
cacheroot, prefix, dbname, preproc_str, ivf_str)
index_cachefile = '%s/%s%s_%s%s,%s.index' % (
cacheroot, prefix, dbname, preproc_str, ivf_str, pqflat_str)
if not use_cache:
preproc_cachefile = None
cent_cachefile = None
index_cachefile = None
print("cachefiles:")
print(preproc_cachefile)
print(cent_cachefile)
print(index_cachefile)
#################################################################
# Wake up GPUs
#################################################################
print("preparing resources for %d GPUs" % ngpu)
gpu_resources = []
for i in range(ngpu):
res = faiss.StandardGpuResources()
if tempmem >= 0:
res.setTempMemory(tempmem)
gpu_resources.append(res)
def make_vres_vdev(i0=0, i1=-1):
" return vectors of device ids and resources useful for gpu_multiple"
vres = faiss.GpuResourcesVector()
vdev = faiss.IntVector()
if i1 == -1:
i1 = ngpu
for i in range(i0, i1):
vdev.push_back(i)
vres.push_back(gpu_resources[i])
return vres, vdev
#################################################################
# Prepare ground truth (for the knngraph)
#################################################################
def compute_GT():
print("compute GT")
t0 = time.time()
gt_I = np.zeros((nq_gt, gt_sl), dtype='int64')
gt_D = np.zeros((nq_gt, gt_sl), dtype='float32')
heaps = faiss.float_maxheap_array_t()
heaps.k = gt_sl
heaps.nh = nq_gt
heaps.val = faiss.swig_ptr(gt_D)
heaps.ids = faiss.swig_ptr(gt_I)
heaps.heapify()
bs = 10 ** 5
n, d = xb.shape
xqs = sanitize(xq[:nq_gt])
db_gt = faiss.IndexFlatL2(d)
vres, vdev = make_vres_vdev()
db_gt_gpu = faiss.index_cpu_to_gpu_multiple(
vres, vdev, db_gt)
# compute ground-truth by blocks of bs, and add to heaps
for i0, xsl in dataset_iterator(xb, IdentPreproc(d), bs):
db_gt_gpu.add(xsl)
D, I = db_gt_gpu.search(xqs, gt_sl)
I += i0
heaps.addn_with_ids(
gt_sl, faiss.swig_ptr(D), faiss.swig_ptr(I), gt_sl)
db_gt_gpu.reset()
print("\r %d/%d, %.3f s" % (i0, n, time.time() - t0), end=' ')
print()
heaps.reorder()
print("GT time: %.3f s" % (time.time() - t0))
return gt_I
if knngraph:
if gt_cachefile and os.path.exists(gt_cachefile):
print("load GT", gt_cachefile)
gt_I = np.load(gt_cachefile)
else:
gt_I = compute_GT()
if gt_cachefile:
print("store GT", gt_cachefile)
np.save(gt_cachefile, gt_I)
#################################################################
# Prepare the vector transformation object (pure CPU)
#################################################################
def train_preprocessor():
print("train preproc", preproc_str)
d = xt.shape[1]
t0 = time.time()
if preproc_str.startswith('OPQ'):
fi = preproc_str[3:-1].split('_')
m = int(fi[0])
dout = int(fi[1]) if len(fi) == 2 else d
preproc = faiss.OPQMatrix(d, m, dout)
elif preproc_str.startswith('PCAR'):
dout = int(preproc_str[4:-1])
preproc = faiss.PCAMatrix(d, dout, 0, True)
else:
assert False
preproc.train(sanitize(xt[:1000000]))
print("preproc train done in %.3f s" % (time.time() - t0))
return preproc
def get_preprocessor():
if preproc_str:
if not preproc_cachefile or not os.path.exists(preproc_cachefile):
preproc = train_preprocessor()
if preproc_cachefile:
print("store", preproc_cachefile)
faiss.write_VectorTransform(preproc, preproc_cachefile)
else:
print("load", preproc_cachefile)
preproc = faiss.read_VectorTransform(preproc_cachefile)
else:
d = xb.shape[1]
preproc = IdentPreproc(d)
return preproc
#################################################################
# Prepare the coarse quantizer
#################################################################
def train_coarse_quantizer(x, k, preproc):
d = preproc.d_out
clus = faiss.Clustering(d, k)
clus.verbose = True
# clus.niter = 2
clus.max_points_per_centroid = 10000000
print("apply preproc on shape", x.shape, 'k=', k)
t0 = time.time()
x = preproc.apply_py(sanitize(x))
print(" preproc %.3f s output shape %s" % (
time.time() - t0, x.shape))
vres, vdev = make_vres_vdev()
index = faiss.index_cpu_to_gpu_multiple(
vres, vdev, faiss.IndexFlatL2(d))
clus.train(x, index)
centroids = faiss.vector_float_to_array(clus.centroids)
return centroids.reshape(k, d)
def prepare_coarse_quantizer(preproc):
if cent_cachefile and os.path.exists(cent_cachefile):
print("load centroids", cent_cachefile)
centroids = np.load(cent_cachefile)
else:
nt = max(1000000, 256 * ncent)
print("train coarse quantizer...")
t0 = time.time()
centroids = train_coarse_quantizer(xt[:nt], ncent, preproc)
print("Coarse train time: %.3f s" % (time.time() - t0))
if cent_cachefile:
print("store centroids", cent_cachefile)
np.save(cent_cachefile, centroids)
coarse_quantizer = faiss.IndexFlatL2(preproc.d_out)
coarse_quantizer.add(centroids)
return coarse_quantizer
#################################################################
# Make index and add elements to it
#################################################################
def prepare_trained_index(preproc):
coarse_quantizer = prepare_coarse_quantizer(preproc)
d = preproc.d_out
if pqflat_str == 'Flat':
print("making an IVFFlat index")
idx_model = faiss.IndexIVFFlat(coarse_quantizer, d, ncent,
faiss.METRIC_L2)
else:
m = int(pqflat_str[2:])
assert m < 56 or use_float16, "PQ%d will work only with -float16" % m
print("making an IVFPQ index, m = ", m)
idx_model = faiss.IndexIVFPQ(coarse_quantizer, d, ncent, m, 8)
coarse_quantizer.this.disown()
idx_model.own_fields = True
# finish training on CPU
t0 = time.time()
print("Training vector codes")
x = preproc.apply_py(sanitize(xt[:1000000]))
idx_model.train(x)
print(" done %.3f s" % (time.time() - t0))
return idx_model
def compute_populated_index(preproc):
"""Add elements to a sharded index. Return the index and if available
a sharded gpu_index that contains the same data. """
indexall = prepare_trained_index(preproc)
co = faiss.GpuMultipleClonerOptions()
co.useFloat16 = use_float16
co.useFloat16CoarseQuantizer = False
co.usePrecomputed = use_precomputed_tables
co.indicesOptions = faiss.INDICES_CPU
co.verbose = True
co.reserveVecs = max_add if max_add > 0 else xb.shape[0]
co.shard = True
assert co.shard_type in (0, 1, 2)
vres, vdev = make_vres_vdev()
gpu_index = faiss.index_cpu_to_gpu_multiple(
vres, vdev, indexall, co)
print("add...")
t0 = time.time()
nb = xb.shape[0]
for i0, xs in dataset_iterator(xb, preproc, add_batch_size):
i1 = i0 + xs.shape[0]
gpu_index.add_with_ids(xs, np.arange(i0, i1))
if max_add > 0 and gpu_index.ntotal > max_add:
print("Flush indexes to CPU")
for i in range(ngpu):
index_src_gpu = faiss.downcast_index(gpu_index.at(i))
index_src = faiss.index_gpu_to_cpu(index_src_gpu)
print(" index %d size %d" % (i, index_src.ntotal))
index_src.copy_subset_to(indexall, 0, 0, nb)
index_src_gpu.reset()
index_src_gpu.reserveMemory(max_add)
gpu_index.sync_with_shard_indexes()
print('\r%d/%d (%.3f s) ' % (
i0, nb, time.time() - t0), end=' ')
sys.stdout.flush()
print("Add time: %.3f s" % (time.time() - t0))
print("Aggregate indexes to CPU")
t0 = time.time()
if hasattr(gpu_index, 'at'):
# it is a sharded index
for i in range(ngpu):
index_src = faiss.index_gpu_to_cpu(gpu_index.at(i))
print(" index %d size %d" % (i, index_src.ntotal))
index_src.copy_subset_to(indexall, 0, 0, nb)
else:
# simple index
index_src = faiss.index_gpu_to_cpu(gpu_index)
index_src.copy_subset_to(indexall, 0, 0, nb)
print(" done in %.3f s" % (time.time() - t0))
if max_add > 0:
# it does not contain all the vectors
gpu_index = None
return gpu_index, indexall
def compute_populated_index_2(preproc):
indexall = prepare_trained_index(preproc)
# set up a 3-stage pipeline that does:
# - stage 1: load + preproc
# - stage 2: assign on GPU
# - stage 3: add to index
stage1 = dataset_iterator(xb, preproc, add_batch_size)
vres, vdev = make_vres_vdev()
coarse_quantizer_gpu = faiss.index_cpu_to_gpu_multiple(
vres, vdev, indexall.quantizer)
def quantize(args):
(i0, xs) = args
_, assign = coarse_quantizer_gpu.search(xs, 1)
return i0, xs, assign.ravel()
stage2 = rate_limited_imap(quantize, stage1)
print("add...")
t0 = time.time()
nb = xb.shape[0]
for i0, xs, assign in stage2:
i1 = i0 + xs.shape[0]
if indexall.__class__ == faiss.IndexIVFPQ:
indexall.add_core_o(i1 - i0, faiss.swig_ptr(xs),
None, None, faiss.swig_ptr(assign))
elif indexall.__class__ == faiss.IndexIVFFlat:
indexall.add_core(i1 - i0, faiss.swig_ptr(xs), None,
faiss.swig_ptr(assign))
else:
assert False
print('\r%d/%d (%.3f s) ' % (
i0, nb, time.time() - t0), end=' ')
sys.stdout.flush()
print("Add time: %.3f s" % (time.time() - t0))
return None, indexall
def get_populated_index(preproc):
if not index_cachefile or not os.path.exists(index_cachefile):
if not altadd:
gpu_index, indexall = compute_populated_index(preproc)
else:
gpu_index, indexall = compute_populated_index_2(preproc)
if index_cachefile:
print("store", index_cachefile)
faiss.write_index(indexall, index_cachefile)
else:
print("load", index_cachefile)
indexall = faiss.read_index(index_cachefile)
gpu_index = None
co = faiss.GpuMultipleClonerOptions()
co.useFloat16 = use_float16
co.useFloat16CoarseQuantizer = False
co.usePrecomputed = use_precomputed_tables
co.indicesOptions = 0
co.verbose = True
co.shard = True # the replicas will be made "manually"
t0 = time.time()
print("CPU index contains %d vectors, move to GPU" % indexall.ntotal)
if replicas == 1:
if not gpu_index:
print("copying loaded index to GPUs")
vres, vdev = make_vres_vdev()
index = faiss.index_cpu_to_gpu_multiple(
vres, vdev, indexall, co)
else:
index = gpu_index
else:
del gpu_index # We override the GPU index
print("Copy CPU index to %d sharded GPU indexes" % replicas)
index = faiss.IndexReplicas()
for i in range(replicas):
gpu0 = ngpu * i / replicas
gpu1 = ngpu * (i + 1) / replicas
vres, vdev = make_vres_vdev(gpu0, gpu1)
print(" dispatch to GPUs %d:%d" % (gpu0, gpu1))
index1 = faiss.index_cpu_to_gpu_multiple(
vres, vdev, indexall, co)
index1.this.disown()
index.addIndex(index1)
index.own_fields = True
del indexall
print("move to GPU done in %.3f s" % (time.time() - t0))
return index
#################################################################
# Perform search
#################################################################
def eval_dataset(index, preproc):
ps = faiss.GpuParameterSpace()
ps.initialize(index)
nq_gt = gt_I.shape[0]
print("search...")
sl = query_batch_size
nq = xq.shape[0]
for nprobe in nprobes:
ps.set_index_parameter(index, 'nprobe', nprobe)
t0 = time.time()
if sl == 0:
D, I = index.search(preproc.apply_py(sanitize(xq)), nnn)
else:
I = np.empty((nq, nnn), dtype='int32')
D = np.empty((nq, nnn), dtype='float32')
inter_res = ''
for i0, xs in dataset_iterator(xq, preproc, sl):
print('\r%d/%d (%.3f s%s) ' % (
i0, nq, time.time() - t0, inter_res), end=' ')
sys.stdout.flush()
i1 = i0 + xs.shape[0]
Di, Ii = index.search(xs, nnn)
I[i0:i1] = Ii
D[i0:i1] = Di
if knngraph and not inter_res and i1 >= nq_gt:
ires = eval_intersection_measure(
gt_I[:, :nnn], I[:nq_gt])
inter_res = ', %.4f' % ires
t1 = time.time()
if knngraph:
ires = eval_intersection_measure(gt_I[:, :nnn], I[:nq_gt])
print(" probe=%-3d: %.3f s rank-%d intersection results: %.4f" % (
nprobe, t1 - t0, nnn, ires))
else:
print(" probe=%-3d: %.3f s" % (nprobe, t1 - t0), end=' ')
gtc = gt_I[:, :1]
nq = xq.shape[0]
for rank in 1, 10, 100:
if rank > nnn: continue
nok = (I[:, :rank] == gtc).sum()
print("1-R@%d: %.4f" % (rank, nok / float(nq)), end=' ')
print()
if I_fname:
I_fname_i = I_fname % I
print("storing", I_fname_i)
np.save(I, I_fname_i)
if D_fname:
D_fname_i = I_fname % I
print("storing", D_fname_i)
np.save(D, D_fname_i)
#################################################################
# Driver
#################################################################
preproc = get_preprocessor()
index = get_populated_index(preproc)
eval_dataset(index, preproc)
# make sure index is deleted before the resources
del index