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IndexIVFFlat.cpp
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IndexIVFFlat.cpp
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/**
* Copyright (c) 2015-present, Facebook, Inc.
* All rights reserved.
*
* This source code is licensed under the BSD+Patents license found in the
* LICENSE file in the root directory of this source tree.
*/
// -*- c++ -*-
#include "IndexIVFFlat.h"
#include <cstdio>
#include "utils.h"
#include "FaissAssert.h"
#include "IndexFlat.h"
#include "AuxIndexStructures.h"
namespace faiss {
/*****************************************
* IndexIVFFlat implementation
******************************************/
IndexIVFFlat::IndexIVFFlat (Index * quantizer,
size_t d, size_t nlist, MetricType metric):
IndexIVF (quantizer, d, nlist, sizeof(float) * d, metric)
{
code_size = sizeof(float) * d;
}
void IndexIVFFlat::add_with_ids (idx_t n, const float * x, const long *xids)
{
add_core (n, x, xids, nullptr);
}
void IndexIVFFlat::add_core (idx_t n, const float * x, const long *xids,
const long *precomputed_idx)
{
FAISS_THROW_IF_NOT (is_trained);
assert (invlists);
FAISS_THROW_IF_NOT_MSG (!(maintain_direct_map && xids),
"cannot have direct map and add with ids");
const long * idx;
ScopeDeleter<long> del;
if (precomputed_idx) {
idx = precomputed_idx;
} else {
long * idx0 = new long [n];
del.set (idx0);
quantizer->assign (n, x, idx0);
idx = idx0;
}
long n_add = 0;
for (size_t i = 0; i < n; i++) {
long id = xids ? xids[i] : ntotal + i;
long list_no = idx [i];
if (list_no < 0)
continue;
const float *xi = x + i * d;
size_t offset = invlists->add_entry (
list_no, id, (const uint8_t*) xi);
if (maintain_direct_map)
direct_map.push_back (list_no << 32 | offset);
n_add++;
}
if (verbose) {
printf("IndexIVFFlat::add_core: added %ld / %ld vectors\n",
n_add, n);
}
ntotal += n_add;
}
namespace {
template<MetricType metric, bool store_pairs, class C>
void search_knn_for_ivf (const IndexIVFFlat & ivf,
size_t nx,
const float * x,
const long * keys,
HeapArray<C> * res,
const IVFSearchParameters *params)
{
long nprobe = params ? params->nprobe : ivf.nprobe;
long max_codes = params ? params->max_codes : ivf.max_codes;
const size_t k = res->k;
size_t nlistv = 0, ndis = 0;
size_t d = ivf.d;
#pragma omp parallel for reduction(+: nlistv, ndis)
for (size_t i = 0; i < nx; i++) {
const float * xi = x + i * d;
const long * keysi = keys + i * nprobe;
float * __restrict simi = res->get_val (i);
long * __restrict idxi = res->get_ids (i);
heap_heapify<C> (k, simi, idxi);
size_t nscan = 0;
for (size_t ik = 0; ik < nprobe; ik++) {
long key = keysi[ik]; /* select the list */
if (key < 0) {
// not enough centroids for multiprobe
continue;
}
FAISS_THROW_IF_NOT_FMT (
key < (long) ivf.nlist,
"Invalid key=%ld at ik=%ld nlist=%ld\n",
key, ik, ivf.nlist);
nlistv++;
size_t list_size = ivf.invlists->list_size(key);
InvertedLists::ScopedCodes scodes (ivf.invlists, key);
const float * list_vecs = (const float*)scodes.get();
const Index::idx_t * ids = store_pairs ? nullptr :
ivf.invlists->get_ids (key);
for (size_t j = 0; j < list_size; j++) {
const float * yj = list_vecs + d * j;
float dis = metric == METRIC_INNER_PRODUCT ?
fvec_inner_product (xi, yj, d) : fvec_L2sqr (xi, yj, d);
if (C::cmp (simi[0], dis)) {
heap_pop<C> (k, simi, idxi);
long id = store_pairs ? (key << 32 | j) : ids[j];
heap_push<C> (k, simi, idxi, dis, id);
}
}
if (ids) {
ivf.invlists->release_ids (ids);
}
nscan += list_size;
if (max_codes && nscan >= max_codes)
break;
}
ndis += nscan;
heap_reorder<C> (k, simi, idxi);
}
indexIVF_stats.nq += nx;
indexIVF_stats.nlist += nlistv;
indexIVF_stats.ndis += ndis;
}
} // anonymous namespace
void IndexIVFFlat::search_preassigned (idx_t n, const float *x, idx_t k,
const idx_t *idx,
const float * /* coarse_dis */,
float *distances, idx_t *labels,
bool store_pairs,
const IVFSearchParameters *params) const
{
if (metric_type == METRIC_INNER_PRODUCT) {
float_minheap_array_t res = {
size_t(n), size_t(k), labels, distances};
if (store_pairs) {
search_knn_for_ivf<METRIC_INNER_PRODUCT, true, CMin<float, long> >
(*this, n, x, idx, &res, params);
} else {
search_knn_for_ivf<METRIC_INNER_PRODUCT, false, CMin<float, long> >
(*this, n, x, idx, &res, params);
}
} else if (metric_type == METRIC_L2) {
float_maxheap_array_t res = {
size_t(n), size_t(k), labels, distances};
if (store_pairs) {
search_knn_for_ivf<METRIC_L2, true, CMax<float, long> >
(*this, n, x, idx, &res, params);
} else {
search_knn_for_ivf<METRIC_L2, false, CMax<float, long> >
(*this, n, x, idx, &res, params);
}
}
}
void IndexIVFFlat::range_search (idx_t nx, const float *x, float radius,
RangeSearchResult *result) const
{
idx_t * keys = new idx_t [nx * nprobe];
ScopeDeleter<idx_t> del (keys);
quantizer->assign (nx, x, keys, nprobe);
#pragma omp parallel
{
RangeSearchPartialResult pres(result);
for (size_t i = 0; i < nx; i++) {
const float * xi = x + i * d;
const long * keysi = keys + i * nprobe;
RangeSearchPartialResult::QueryResult & qres =
pres.new_result (i);
for (size_t ik = 0; ik < nprobe; ik++) {
long key = keysi[ik]; /* select the list */
if (key < 0 || key >= (long) nlist) {
fprintf (stderr, "Invalid key=%ld at ik=%ld nlist=%ld\n",
key, ik, nlist);
throw;
}
const size_t list_size = invlists->list_size(key);
InvertedLists::ScopedCodes scodes (invlists, key);
const float * list_vecs = (const float*)scodes.get();
InvertedLists::ScopedIds ids (invlists, key);
for (size_t j = 0; j < list_size; j++) {
const float * yj = list_vecs + d * j;
if (metric_type == METRIC_L2) {
float disij = fvec_L2sqr (xi, yj, d);
if (disij < radius) {
qres.add (disij, ids[j]);
}
} else if (metric_type == METRIC_INNER_PRODUCT) {
float disij = fvec_inner_product(xi, yj, d);
if (disij > radius) {
qres.add (disij, ids[j]);
}
}
}
}
}
pres.finalize ();
}
}
void IndexIVFFlat::update_vectors (int n, idx_t *new_ids, const float *x)
{
FAISS_THROW_IF_NOT (maintain_direct_map);
FAISS_THROW_IF_NOT (is_trained);
std::vector<idx_t> assign (n);
quantizer->assign (n, x, assign.data());
for (size_t i = 0; i < n; i++) {
idx_t id = new_ids[i];
FAISS_THROW_IF_NOT_MSG (0 <= id && id < ntotal,
"id to update out of range");
{ // remove old one
long dm = direct_map[id];
long ofs = dm & 0xffffffff;
long il = dm >> 32;
size_t l = invlists->list_size (il);
if (ofs != l - 1) { // move l - 1 to ofs
long id2 = invlists->get_single_id (il, l - 1);
direct_map[id2] = (il << 32) | ofs;
invlists->update_entry (il, ofs, id2,
invlists->get_single_code (il, l - 1));
}
invlists->resize (il, l - 1);
}
{ // insert new one
long il = assign[i];
size_t l = invlists->list_size (il);
long dm = (il << 32) | l;
direct_map[id] = dm;
invlists->add_entry (il, id, (const uint8_t*)(x + i * d));
}
}
}
void IndexIVFFlat::reconstruct_from_offset (long list_no, long offset,
float* recons) const
{
memcpy (recons, invlists->get_single_code (list_no, offset), code_size);
}
/*****************************************
* IndexIVFFlatDedup implementation
******************************************/
IndexIVFFlatDedup::IndexIVFFlatDedup (
Index * quantizer, size_t d, size_t nlist_,
MetricType metric_type):
IndexIVFFlat (quantizer, d, nlist_, metric_type)
{}
// from Python's stringobject.c
static uint64_t hash_bytes (const uint8_t *bytes, long n) {
const uint8_t *p = bytes;
uint64_t x = (uint64_t)(*p) << 7;
long len = n;
while (--len >= 0) {
x = (1000003*x) ^ *p++;
}
x ^= n;
return x;
}
void IndexIVFFlatDedup::train(idx_t n, const float* x)
{
std::unordered_map<uint64_t, idx_t> map;
float * x2 = new float [n * d];
ScopeDeleter<float> del (x2);
long n2 = 0;
for (long i = 0; i < n; i++) {
uint64_t hash = hash_bytes((uint8_t *)(x + i * d), code_size);
if (map.count(hash) &&
!memcmp (x2 + map[hash] * d, x + i * d, code_size)) {
// is duplicate, skip
} else {
map [hash] = n2;
memcpy (x2 + n2 * d, x + i * d, code_size);
n2 ++;
}
}
if (verbose) {
printf ("IndexIVFFlatDedup::train: train on %ld points after dedup "
"(was %ld points)\n", n2, n);
}
IndexIVFFlat::train (n2, x2);
}
void IndexIVFFlatDedup::add_with_ids(
idx_t na, const float* x, const long* xids)
{
FAISS_THROW_IF_NOT (is_trained);
assert (invlists);
FAISS_THROW_IF_NOT_MSG (
!maintain_direct_map,
"IVFFlatDedup not implemented with direct_map");
long * idx = new long [na];
ScopeDeleter<long> del (idx);
quantizer->assign (na, x, idx);
long n_add = 0, n_dup = 0;
// TODO make a omp loop with this
for (size_t i = 0; i < na; i++) {
idx_t id = xids ? xids[i] : ntotal + i;
long list_no = idx [i];
if (list_no < 0) {
continue;
}
const float *xi = x + i * d;
// search if there is already an entry with that id
InvertedLists::ScopedCodes codes (invlists, list_no);
long n = invlists->list_size (list_no);
long offset = -1;
for (long o = 0; o < n; o++) {
if (!memcmp (codes.get() + o * code_size,
xi, code_size)) {
offset = o;
break;
}
}
if (offset == -1) { // not found
invlists->add_entry (list_no, id, (const uint8_t*) xi);
} else {
// mark equivalence
idx_t id2 = invlists->get_single_id (list_no, offset);
std::pair<idx_t, idx_t> pair (id2, id);
instances.insert (pair);
n_dup ++;
}
n_add++;
}
if (verbose) {
printf("IndexIVFFlat::add_with_ids: added %ld / %ld vectors"
" (out of which %ld are duplicates)\n",
n_add, na, n_dup);
}
ntotal += n_add;
}
void IndexIVFFlatDedup::search_preassigned (
idx_t n, const float *x, idx_t k,
const idx_t *assign,
const float *centroid_dis,
float *distances, idx_t *labels,
bool store_pairs,
const IVFSearchParameters *params) const
{
FAISS_THROW_IF_NOT_MSG (
!store_pairs, "store_pairs not supported in IVFDedup");
IndexIVFFlat::search_preassigned (n, x, k, assign, centroid_dis,
distances, labels, false,
params);
std::vector <idx_t> labels2 (k);
std::vector <float> dis2 (k);
for (long i = 0; i < n; i++) {
idx_t *labels1 = labels + i * k;
float *dis1 = distances + i * k;
long j = 0;
for (; j < k; j++) {
if (instances.find (labels1[j]) != instances.end ()) {
// a duplicate: special handling
break;
}
}
if (j < k) {
// there are duplicates, special handling
long j0 = j;
long rp = j;
while (j < k) {
auto range = instances.equal_range (labels1[rp]);
float dis = dis1[rp];
labels2[j] = labels1[rp];
dis2[j] = dis;
j ++;
for (auto it = range.first; j < k && it != range.second; ++it) {
labels2[j] = it->second;
dis2[j] = dis;
j++;
}
rp++;
}
memcpy (labels1 + j0, labels2.data() + j0,
sizeof(labels1[0]) * (k - j0));
memcpy (dis1 + j0, dis2.data() + j0,
sizeof(dis2[0]) * (k - j0));
}
}
}
long IndexIVFFlatDedup::remove_ids(const IDSelector& sel)
{
std::unordered_map<idx_t, idx_t> replace;
std::vector<std::pair<idx_t, idx_t> > toadd;
for (auto it = instances.begin(); it != instances.end(); ) {
if (sel.is_member(it->first)) {
// then we erase this entry
if (!sel.is_member(it->second)) {
// if the second is not erased
if (replace.count(it->first) == 0) {
replace[it->first] = it->second;
} else { // remember we should add an element
std::pair<idx_t, idx_t> new_entry (
replace[it->first], it->second);
toadd.push_back(new_entry);
}
}
it = instances.erase(it);
} else {
if (sel.is_member(it->second)) {
it = instances.erase(it);
} else {
++it;
}
}
}
instances.insert (toadd.begin(), toadd.end());
// mostly copied from IndexIVF.cpp
FAISS_THROW_IF_NOT_MSG (!maintain_direct_map,
"direct map remove not implemented");
std::vector<long> toremove(nlist);
#pragma omp parallel for
for (long i = 0; i < nlist; i++) {
long l0 = invlists->list_size (i), l = l0, j = 0;
InvertedLists::ScopedIds idsi (invlists, i);
while (j < l) {
if (sel.is_member (idsi[j])) {
if (replace.count(idsi[j]) == 0) {
l--;
invlists->update_entry (
i, j,
invlists->get_single_id (i, l),
InvertedLists::ScopedCodes (invlists, i, l).get());
} else {
invlists->update_entry (
i, j,
replace[idsi[j]],
InvertedLists::ScopedCodes (invlists, i, j).get());
j++;
}
} else {
j++;
}
}
toremove[i] = l0 - l;
}
// this will not run well in parallel on ondisk because of possible shrinks
long nremove = 0;
for (long i = 0; i < nlist; i++) {
if (toremove[i] > 0) {
nremove += toremove[i];
invlists->resize(
i, invlists->list_size(i) - toremove[i]);
}
}
ntotal -= nremove;
return nremove;
}
void IndexIVFFlatDedup::range_search(
idx_t ,
const float* ,
float ,
RangeSearchResult* ) const
{
FAISS_THROW_MSG ("not implemented");
}
void IndexIVFFlatDedup::update_vectors (int , idx_t *, const float *)
{
FAISS_THROW_MSG ("not implemented");
}
void IndexIVFFlatDedup::reconstruct_from_offset (
long , long ,
float* ) const
{
FAISS_THROW_MSG ("not implemented");
}
} // namespace faiss