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IndexIVF.cpp
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IndexIVF.cpp
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/**
* 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.
*/
// -*- c++ -*-
#include <faiss/IndexIVF.h>
#include <omp.h>
#include <cstdio>
#include <memory>
#include <faiss/utils/utils.h>
#include <faiss/utils/hamming.h>
#include <faiss/impl/FaissAssert.h>
#include <faiss/IndexFlat.h>
#include <faiss/impl/AuxIndexStructures.h>
namespace faiss {
using ScopedIds = InvertedLists::ScopedIds;
using ScopedCodes = InvertedLists::ScopedCodes;
/*****************************************
* Level1Quantizer implementation
******************************************/
Level1Quantizer::Level1Quantizer (Index * quantizer, size_t nlist):
quantizer (quantizer),
nlist (nlist),
quantizer_trains_alone (0),
own_fields (false),
clustering_index (nullptr)
{
// here we set a low # iterations because this is typically used
// for large clusterings (nb this is not used for the MultiIndex,
// for which quantizer_trains_alone = true)
cp.niter = 10;
}
Level1Quantizer::Level1Quantizer ():
quantizer (nullptr),
nlist (0),
quantizer_trains_alone (0), own_fields (false),
clustering_index (nullptr)
{}
Level1Quantizer::~Level1Quantizer ()
{
if (own_fields) delete quantizer;
}
void Level1Quantizer::train_q1 (size_t n, const float *x, bool verbose, MetricType metric_type)
{
size_t d = quantizer->d;
if (quantizer->is_trained && (quantizer->ntotal == nlist)) {
if (verbose)
printf ("IVF quantizer does not need training.\n");
} else if (quantizer_trains_alone == 1) {
if (verbose)
printf ("IVF quantizer trains alone...\n");
quantizer->train (n, x);
quantizer->verbose = verbose;
FAISS_THROW_IF_NOT_MSG (quantizer->ntotal == nlist,
"nlist not consistent with quantizer size");
} else if (quantizer_trains_alone == 0) {
if (verbose)
printf ("Training level-1 quantizer on %ld vectors in %ldD\n",
n, d);
Clustering clus (d, nlist, cp);
quantizer->reset();
if (clustering_index) {
clus.train (n, x, *clustering_index);
quantizer->add (nlist, clus.centroids.data());
} else {
clus.train (n, x, *quantizer);
}
quantizer->is_trained = true;
} else if (quantizer_trains_alone == 2) {
if (verbose)
printf (
"Training L2 quantizer on %ld vectors in %ldD%s\n",
n, d,
clustering_index ? "(user provided index)" : "");
FAISS_THROW_IF_NOT (metric_type == METRIC_L2);
Clustering clus (d, nlist, cp);
if (!clustering_index) {
IndexFlatL2 assigner (d);
clus.train(n, x, assigner);
} else {
clus.train(n, x, *clustering_index);
}
if (verbose)
printf ("Adding centroids to quantizer\n");
quantizer->add (nlist, clus.centroids.data());
}
}
size_t Level1Quantizer::coarse_code_size () const
{
size_t nl = nlist - 1;
size_t nbyte = 0;
while (nl > 0) {
nbyte ++;
nl >>= 8;
}
return nbyte;
}
void Level1Quantizer::encode_listno (Index::idx_t list_no, uint8_t *code) const
{
// little endian
size_t nl = nlist - 1;
while (nl > 0) {
*code++ = list_no & 0xff;
list_no >>= 8;
nl >>= 8;
}
}
Index::idx_t Level1Quantizer::decode_listno (const uint8_t *code) const
{
size_t nl = nlist - 1;
int64_t list_no = 0;
int nbit = 0;
while (nl > 0) {
list_no |= int64_t(*code++) << nbit;
nbit += 8;
nl >>= 8;
}
FAISS_THROW_IF_NOT (list_no >= 0 && list_no < nlist);
return list_no;
}
/*****************************************
* IndexIVF implementation
******************************************/
IndexIVF::IndexIVF (Index * quantizer, size_t d,
size_t nlist, size_t code_size,
MetricType metric):
Index (d, metric),
Level1Quantizer (quantizer, nlist),
invlists (new ArrayInvertedLists (nlist, code_size)),
own_invlists (true),
code_size (code_size),
nprobe (1),
max_codes (0),
parallel_mode (0)
{
FAISS_THROW_IF_NOT (d == quantizer->d);
is_trained = quantizer->is_trained && (quantizer->ntotal == nlist);
// Spherical by default if the metric is inner_product
if (metric_type == METRIC_INNER_PRODUCT) {
cp.spherical = true;
}
}
IndexIVF::IndexIVF ():
invlists (nullptr), own_invlists (false),
code_size (0),
nprobe (1), max_codes (0), parallel_mode (0)
{}
void IndexIVF::add (idx_t n, const float * x)
{
add_with_ids (n, x, nullptr);
}
void IndexIVF::add_with_ids (idx_t n, const float * x, const idx_t *xids)
{
// do some blocking to avoid excessive allocs
idx_t bs = 65536;
if (n > bs) {
for (idx_t i0 = 0; i0 < n; i0 += bs) {
idx_t i1 = std::min (n, i0 + bs);
if (verbose) {
printf(" IndexIVF::add_with_ids %ld:%ld\n", i0, i1);
}
add_with_ids (i1 - i0, x + i0 * d,
xids ? xids + i0 : nullptr);
}
return;
}
FAISS_THROW_IF_NOT (is_trained);
direct_map.check_can_add (xids);
std::unique_ptr<idx_t []> idx(new idx_t[n]);
quantizer->assign (n, x, idx.get());
size_t nadd = 0, nminus1 = 0;
for (size_t i = 0; i < n; i++) {
if (idx[i] < 0) nminus1++;
}
std::unique_ptr<uint8_t []> flat_codes(new uint8_t [n * code_size]);
encode_vectors (n, x, idx.get(), flat_codes.get());
DirectMapAdd dm_adder(direct_map, n, xids);
#pragma omp parallel reduction(+: nadd)
{
int nt = omp_get_num_threads();
int rank = omp_get_thread_num();
// each thread takes care of a subset of lists
for (size_t i = 0; i < n; i++) {
idx_t list_no = idx [i];
if (list_no >= 0 && list_no % nt == rank) {
idx_t id = xids ? xids[i] : ntotal + i;
size_t ofs = invlists->add_entry (
list_no, id,
flat_codes.get() + i * code_size
);
dm_adder.add (i, list_no, ofs);
nadd++;
} else if (rank == 0 && list_no == -1) {
dm_adder.add (i, -1, 0);
}
}
}
if (verbose) {
printf(" added %ld / %ld vectors (%ld -1s)\n", nadd, n, nminus1);
}
ntotal += n;
}
void IndexIVF::make_direct_map (bool b)
{
if (b) {
direct_map.set_type (DirectMap::Array, invlists, ntotal);
} else {
direct_map.set_type (DirectMap::NoMap, invlists, ntotal);
}
}
void IndexIVF::set_direct_map_type (DirectMap::Type type)
{
direct_map.set_type (type, invlists, ntotal);
}
void IndexIVF::search (idx_t n, const float *x, idx_t k,
float *distances, idx_t *labels) const
{
std::unique_ptr<idx_t[]> idx(new idx_t[n * nprobe]);
std::unique_ptr<float[]> coarse_dis(new float[n * nprobe]);
double t0 = getmillisecs();
quantizer->search (n, x, nprobe, coarse_dis.get(), idx.get());
indexIVF_stats.quantization_time += getmillisecs() - t0;
t0 = getmillisecs();
invlists->prefetch_lists (idx.get(), n * nprobe);
search_preassigned (n, x, k, idx.get(), coarse_dis.get(),
distances, labels, false);
indexIVF_stats.search_time += getmillisecs() - t0;
}
void IndexIVF::search_preassigned (idx_t n, const float *x, idx_t k,
const idx_t *keys,
const float *coarse_dis ,
float *distances, idx_t *labels,
bool store_pairs,
const IVFSearchParameters *params) const
{
long nprobe = params ? params->nprobe : this->nprobe;
long max_codes = params ? params->max_codes : this->max_codes;
size_t nlistv = 0, ndis = 0, nheap = 0;
using HeapForIP = CMin<float, idx_t>;
using HeapForL2 = CMax<float, idx_t>;
bool interrupt = false;
int pmode = this->parallel_mode & ~PARALLEL_MODE_NO_HEAP_INIT;
bool do_heap_init = !(this->parallel_mode & PARALLEL_MODE_NO_HEAP_INIT);
// don't start parallel section if single query
bool do_parallel =
pmode == 0 ? n > 1 :
pmode == 1 ? nprobe > 1 :
nprobe * n > 1;
#pragma omp parallel if(do_parallel) reduction(+: nlistv, ndis, nheap)
{
InvertedListScanner *scanner = get_InvertedListScanner(store_pairs);
ScopeDeleter1<InvertedListScanner> del(scanner);
/*****************************************************
* Depending on parallel_mode, there are two possible ways
* to organize the search. Here we define local functions
* that are in common between the two
******************************************************/
// intialize + reorder a result heap
auto init_result = [&](float *simi, idx_t *idxi) {
if (!do_heap_init) return;
if (metric_type == METRIC_INNER_PRODUCT) {
heap_heapify<HeapForIP> (k, simi, idxi);
} else {
heap_heapify<HeapForL2> (k, simi, idxi);
}
};
auto reorder_result = [&] (float *simi, idx_t *idxi) {
if (!do_heap_init) return;
if (metric_type == METRIC_INNER_PRODUCT) {
heap_reorder<HeapForIP> (k, simi, idxi);
} else {
heap_reorder<HeapForL2> (k, simi, idxi);
}
};
// single list scan using the current scanner (with query
// set porperly) and storing results in simi and idxi
auto scan_one_list = [&] (idx_t key, float coarse_dis_i,
float *simi, idx_t *idxi) {
if (key < 0) {
// not enough centroids for multiprobe
return (size_t)0;
}
FAISS_THROW_IF_NOT_FMT (key < (idx_t) nlist,
"Invalid key=%ld nlist=%ld\n",
key, nlist);
size_t list_size = invlists->list_size(key);
// don't waste time on empty lists
if (list_size == 0) {
return (size_t)0;
}
scanner->set_list (key, coarse_dis_i);
nlistv++;
InvertedLists::ScopedCodes scodes (invlists, key);
std::unique_ptr<InvertedLists::ScopedIds> sids;
const Index::idx_t * ids = nullptr;
if (!store_pairs) {
sids.reset (new InvertedLists::ScopedIds (invlists, key));
ids = sids->get();
}
nheap += scanner->scan_codes (list_size, scodes.get(),
ids, simi, idxi, k);
return list_size;
};
/****************************************************
* Actual loops, depending on parallel_mode
****************************************************/
if (pmode == 0) {
#pragma omp for
for (size_t i = 0; i < n; i++) {
if (interrupt) {
continue;
}
// loop over queries
scanner->set_query (x + i * d);
float * simi = distances + i * k;
idx_t * idxi = labels + i * k;
init_result (simi, idxi);
long nscan = 0;
// loop over probes
for (size_t ik = 0; ik < nprobe; ik++) {
nscan += scan_one_list (
keys [i * nprobe + ik],
coarse_dis[i * nprobe + ik],
simi, idxi
);
if (max_codes && nscan >= max_codes) {
break;
}
}
ndis += nscan;
reorder_result (simi, idxi);
if (InterruptCallback::is_interrupted ()) {
interrupt = true;
}
} // parallel for
} else if (pmode == 1) {
std::vector <idx_t> local_idx (k);
std::vector <float> local_dis (k);
for (size_t i = 0; i < n; i++) {
scanner->set_query (x + i * d);
init_result (local_dis.data(), local_idx.data());
#pragma omp for schedule(dynamic)
for (size_t ik = 0; ik < nprobe; ik++) {
ndis += scan_one_list
(keys [i * nprobe + ik],
coarse_dis[i * nprobe + ik],
local_dis.data(), local_idx.data());
// can't do the test on max_codes
}
// merge thread-local results
float * simi = distances + i * k;
idx_t * idxi = labels + i * k;
#pragma omp single
init_result (simi, idxi);
#pragma omp barrier
#pragma omp critical
{
if (metric_type == METRIC_INNER_PRODUCT) {
heap_addn<HeapForIP>
(k, simi, idxi,
local_dis.data(), local_idx.data(), k);
} else {
heap_addn<HeapForL2>
(k, simi, idxi,
local_dis.data(), local_idx.data(), k);
}
}
#pragma omp barrier
#pragma omp single
reorder_result (simi, idxi);
}
} else {
FAISS_THROW_FMT ("parallel_mode %d not supported\n",
pmode);
}
} // parallel section
if (interrupt) {
FAISS_THROW_MSG ("computation interrupted");
}
indexIVF_stats.nq += n;
indexIVF_stats.nlist += nlistv;
indexIVF_stats.ndis += ndis;
indexIVF_stats.nheap_updates += nheap;
}
void IndexIVF::range_search (idx_t nx, const float *x, float radius,
RangeSearchResult *result) const
{
std::unique_ptr<idx_t[]> keys (new idx_t[nx * nprobe]);
std::unique_ptr<float []> coarse_dis (new float[nx * nprobe]);
double t0 = getmillisecs();
quantizer->search (nx, x, nprobe, coarse_dis.get (), keys.get ());
indexIVF_stats.quantization_time += getmillisecs() - t0;
t0 = getmillisecs();
invlists->prefetch_lists (keys.get(), nx * nprobe);
range_search_preassigned (nx, x, radius, keys.get (), coarse_dis.get (),
result);
indexIVF_stats.search_time += getmillisecs() - t0;
}
void IndexIVF::range_search_preassigned (
idx_t nx, const float *x, float radius,
const idx_t *keys, const float *coarse_dis,
RangeSearchResult *result) const
{
size_t nlistv = 0, ndis = 0;
bool store_pairs = false;
std::vector<RangeSearchPartialResult *> all_pres (omp_get_max_threads());
#pragma omp parallel reduction(+: nlistv, ndis)
{
RangeSearchPartialResult pres(result);
std::unique_ptr<InvertedListScanner> scanner
(get_InvertedListScanner(store_pairs));
FAISS_THROW_IF_NOT (scanner.get ());
all_pres[omp_get_thread_num()] = &pres;
// prepare the list scanning function
auto scan_list_func = [&](size_t i, size_t ik, RangeQueryResult &qres) {
idx_t key = keys[i * nprobe + ik]; /* select the list */
if (key < 0) return;
FAISS_THROW_IF_NOT_FMT (
key < (idx_t) nlist,
"Invalid key=%ld at ik=%ld nlist=%ld\n",
key, ik, nlist);
const size_t list_size = invlists->list_size(key);
if (list_size == 0) return;
InvertedLists::ScopedCodes scodes (invlists, key);
InvertedLists::ScopedIds ids (invlists, key);
scanner->set_list (key, coarse_dis[i * nprobe + ik]);
nlistv++;
ndis += list_size;
scanner->scan_codes_range (list_size, scodes.get(),
ids.get(), radius, qres);
};
if (parallel_mode == 0) {
#pragma omp for
for (size_t i = 0; i < nx; i++) {
scanner->set_query (x + i * d);
RangeQueryResult & qres = pres.new_result (i);
for (size_t ik = 0; ik < nprobe; ik++) {
scan_list_func (i, ik, qres);
}
}
} else if (parallel_mode == 1) {
for (size_t i = 0; i < nx; i++) {
scanner->set_query (x + i * d);
RangeQueryResult & qres = pres.new_result (i);
#pragma omp for schedule(dynamic)
for (size_t ik = 0; ik < nprobe; ik++) {
scan_list_func (i, ik, qres);
}
}
} else if (parallel_mode == 2) {
std::vector<RangeQueryResult *> all_qres (nx);
RangeQueryResult *qres = nullptr;
#pragma omp for schedule(dynamic)
for (size_t iik = 0; iik < nx * nprobe; iik++) {
size_t i = iik / nprobe;
size_t ik = iik % nprobe;
if (qres == nullptr || qres->qno != i) {
FAISS_ASSERT (!qres || i > qres->qno);
qres = &pres.new_result (i);
scanner->set_query (x + i * d);
}
scan_list_func (i, ik, *qres);
}
} else {
FAISS_THROW_FMT ("parallel_mode %d not supported\n", parallel_mode);
}
if (parallel_mode == 0) {
pres.finalize ();
} else {
#pragma omp barrier
#pragma omp single
RangeSearchPartialResult::merge (all_pres, false);
#pragma omp barrier
}
}
indexIVF_stats.nq += nx;
indexIVF_stats.nlist += nlistv;
indexIVF_stats.ndis += ndis;
}
InvertedListScanner *IndexIVF::get_InvertedListScanner (
bool /*store_pairs*/) const
{
return nullptr;
}
void IndexIVF::reconstruct (idx_t key, float* recons) const
{
idx_t lo = direct_map.get (key);
reconstruct_from_offset (lo_listno(lo), lo_offset(lo), recons);
}
void IndexIVF::reconstruct_n (idx_t i0, idx_t ni, float* recons) const
{
FAISS_THROW_IF_NOT (ni == 0 || (i0 >= 0 && i0 + ni <= ntotal));
for (idx_t list_no = 0; list_no < nlist; list_no++) {
size_t list_size = invlists->list_size (list_no);
ScopedIds idlist (invlists, list_no);
for (idx_t offset = 0; offset < list_size; offset++) {
idx_t id = idlist[offset];
if (!(id >= i0 && id < i0 + ni)) {
continue;
}
float* reconstructed = recons + (id - i0) * d;
reconstruct_from_offset (list_no, offset, reconstructed);
}
}
}
/* standalone codec interface */
size_t IndexIVF::sa_code_size () const
{
size_t coarse_size = coarse_code_size();
return code_size + coarse_size;
}
void IndexIVF::sa_encode (idx_t n, const float *x,
uint8_t *bytes) const
{
FAISS_THROW_IF_NOT (is_trained);
std::unique_ptr<int64_t []> idx (new int64_t [n]);
quantizer->assign (n, x, idx.get());
encode_vectors (n, x, idx.get(), bytes, true);
}
void IndexIVF::search_and_reconstruct (idx_t n, const float *x, idx_t k,
float *distances, idx_t *labels,
float *recons) const
{
idx_t * idx = new idx_t [n * nprobe];
ScopeDeleter<idx_t> del (idx);
float * coarse_dis = new float [n * nprobe];
ScopeDeleter<float> del2 (coarse_dis);
quantizer->search (n, x, nprobe, coarse_dis, idx);
invlists->prefetch_lists (idx, n * nprobe);
// search_preassigned() with `store_pairs` enabled to obtain the list_no
// and offset into `codes` for reconstruction
search_preassigned (n, x, k, idx, coarse_dis,
distances, labels, true /* store_pairs */);
for (idx_t i = 0; i < n; ++i) {
for (idx_t j = 0; j < k; ++j) {
idx_t ij = i * k + j;
idx_t key = labels[ij];
float* reconstructed = recons + ij * d;
if (key < 0) {
// Fill with NaNs
memset(reconstructed, -1, sizeof(*reconstructed) * d);
} else {
int list_no = lo_listno (key);
int offset = lo_offset (key);
// Update label to the actual id
labels[ij] = invlists->get_single_id (list_no, offset);
reconstruct_from_offset (list_no, offset, reconstructed);
}
}
}
}
void IndexIVF::reconstruct_from_offset(
int64_t /*list_no*/,
int64_t /*offset*/,
float* /*recons*/) const {
FAISS_THROW_MSG ("reconstruct_from_offset not implemented");
}
void IndexIVF::reset ()
{
direct_map.clear ();
invlists->reset ();
ntotal = 0;
}
size_t IndexIVF::remove_ids (const IDSelector & sel)
{
size_t nremove = direct_map.remove_ids (sel, invlists);
ntotal -= nremove;
return nremove;
}
void IndexIVF::update_vectors (int n, const idx_t *new_ids, const float *x)
{
if (direct_map.type == DirectMap::Hashtable) {
// just remove then add
IDSelectorArray sel(n, new_ids);
size_t nremove = remove_ids (sel);
FAISS_THROW_IF_NOT_MSG (nremove == n,
"did not find all entries to remove");
add_with_ids (n, x, new_ids);
return;
}
FAISS_THROW_IF_NOT (direct_map.type == DirectMap::Array);
// here it is more tricky because we don't want to introduce holes
// in continuous range of ids
FAISS_THROW_IF_NOT (is_trained);
std::vector<idx_t> assign (n);
quantizer->assign (n, x, assign.data());
std::vector<uint8_t> flat_codes (n * code_size);
encode_vectors (n, x, assign.data(), flat_codes.data());
direct_map.update_codes (invlists, n, new_ids, assign.data(), flat_codes.data());
}
void IndexIVF::train (idx_t n, const float *x)
{
if (verbose)
printf ("Training level-1 quantizer\n");
train_q1 (n, x, verbose, metric_type);
if (verbose)
printf ("Training IVF residual\n");
train_residual (n, x);
is_trained = true;
}
void IndexIVF::train_residual(idx_t /*n*/, const float* /*x*/) {
if (verbose)
printf("IndexIVF: no residual training\n");
// does nothing by default
}
void IndexIVF::check_compatible_for_merge (const IndexIVF &other) const
{
// minimal sanity checks
FAISS_THROW_IF_NOT (other.d == d);
FAISS_THROW_IF_NOT (other.nlist == nlist);
FAISS_THROW_IF_NOT (other.code_size == code_size);
FAISS_THROW_IF_NOT_MSG (typeid (*this) == typeid (other),
"can only merge indexes of the same type");
FAISS_THROW_IF_NOT_MSG (this->direct_map.no() && other.direct_map.no(),
"merge direct_map not implemented");
}
void IndexIVF::merge_from (IndexIVF &other, idx_t add_id)
{
check_compatible_for_merge (other);
invlists->merge_from (other.invlists, add_id);
ntotal += other.ntotal;
other.ntotal = 0;
}
void IndexIVF::replace_invlists (InvertedLists *il, bool own)
{
if (own_invlists) {
delete invlists;
}
// FAISS_THROW_IF_NOT (ntotal == 0);
if (il) {
FAISS_THROW_IF_NOT (il->nlist == nlist &&
il->code_size == code_size);
}
invlists = il;
own_invlists = own;
}
void IndexIVF::copy_subset_to (IndexIVF & other, int subset_type,
idx_t a1, idx_t a2) const
{
FAISS_THROW_IF_NOT (nlist == other.nlist);
FAISS_THROW_IF_NOT (code_size == other.code_size);
FAISS_THROW_IF_NOT (other.direct_map.no());
FAISS_THROW_IF_NOT_FMT (
subset_type == 0 || subset_type == 1 || subset_type == 2,
"subset type %d not implemented", subset_type);
size_t accu_n = 0;
size_t accu_a1 = 0;
size_t accu_a2 = 0;
InvertedLists *oivf = other.invlists;
for (idx_t list_no = 0; list_no < nlist; list_no++) {
size_t n = invlists->list_size (list_no);
ScopedIds ids_in (invlists, list_no);
if (subset_type == 0) {
for (idx_t i = 0; i < n; i++) {
idx_t id = ids_in[i];
if (a1 <= id && id < a2) {
oivf->add_entry (list_no,
invlists->get_single_id (list_no, i),
ScopedCodes (invlists, list_no, i).get());
other.ntotal++;
}
}
} else if (subset_type == 1) {
for (idx_t i = 0; i < n; i++) {
idx_t id = ids_in[i];
if (id % a1 == a2) {
oivf->add_entry (list_no,
invlists->get_single_id (list_no, i),
ScopedCodes (invlists, list_no, i).get());
other.ntotal++;
}
}
} else if (subset_type == 2) {
// see what is allocated to a1 and to a2
size_t next_accu_n = accu_n + n;
size_t next_accu_a1 = next_accu_n * a1 / ntotal;
size_t i1 = next_accu_a1 - accu_a1;
size_t next_accu_a2 = next_accu_n * a2 / ntotal;
size_t i2 = next_accu_a2 - accu_a2;
for (idx_t i = i1; i < i2; i++) {
oivf->add_entry (list_no,
invlists->get_single_id (list_no, i),
ScopedCodes (invlists, list_no, i).get());
}
other.ntotal += i2 - i1;
accu_a1 = next_accu_a1;
accu_a2 = next_accu_a2;
}
accu_n += n;
}
FAISS_ASSERT(accu_n == ntotal);
}
IndexIVF::~IndexIVF()
{
if (own_invlists) {
delete invlists;
}
}
void IndexIVFStats::reset()
{
memset ((void*)this, 0, sizeof (*this));
}
IndexIVFStats indexIVF_stats;
void InvertedListScanner::scan_codes_range (size_t ,
const uint8_t *,
const idx_t *,
float ,
RangeQueryResult &) const
{
FAISS_THROW_MSG ("scan_codes_range not implemented");
}
} // namespace faiss