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Index2Layer.cpp
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Index2Layer.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/Index2Layer.h>
#include <cmath>
#include <cstdio>
#include <cassert>
#include <stdint.h>
#ifdef __SSE__
#include <immintrin.h>
#endif
#include <algorithm>
#include <faiss/IndexIVFPQ.h>
#include <faiss/impl/FaissAssert.h>
#include <faiss/utils/utils.h>
#include <faiss/impl/AuxIndexStructures.h>
#include <faiss/IndexFlat.h>
#include <faiss/utils/distances.h>
/*
#include <faiss/utils/Heap.h>
#include <faiss/Clustering.h>
#include <faiss/utils/hamming.h>
*/
namespace faiss {
/*************************************
* Index2Layer implementation
*************************************/
Index2Layer::Index2Layer (Index * quantizer, size_t nlist,
int M, int nbit,
MetricType metric):
Index (quantizer->d, metric),
q1 (quantizer, nlist),
pq (quantizer->d, M, nbit)
{
is_trained = false;
for (int nbyte = 0; nbyte < 7; nbyte++) {
if ((1L << (8 * nbyte)) >= nlist) {
code_size_1 = nbyte;
break;
}
}
code_size_2 = pq.code_size;
code_size = code_size_1 + code_size_2;
}
Index2Layer::Index2Layer ()
{
code_size = code_size_1 = code_size_2 = 0;
}
Index2Layer::~Index2Layer ()
{}
void Index2Layer::train(idx_t n, const float* x)
{
if (verbose) {
printf ("training level-1 quantizer %ld vectors in %dD\n",
n, d);
}
q1.train_q1 (n, x, verbose, metric_type);
if (verbose) {
printf("computing residuals\n");
}
const float * x_in = x;
x = fvecs_maybe_subsample (
d, (size_t*)&n, pq.cp.max_points_per_centroid * pq.ksub,
x, verbose, pq.cp.seed);
ScopeDeleter<float> del_x (x_in == x ? nullptr : x);
std::vector<idx_t> assign(n); // assignement to coarse centroids
q1.quantizer->assign (n, x, assign.data());
std::vector<float> residuals(n * d);
for (idx_t i = 0; i < n; i++) {
q1.quantizer->compute_residual (
x + i * d, residuals.data() + i * d, assign[i]);
}
if (verbose)
printf ("training %zdx%zd product quantizer on %ld vectors in %dD\n",
pq.M, pq.ksub, n, d);
pq.verbose = verbose;
pq.train (n, residuals.data());
is_trained = true;
}
void Index2Layer::add(idx_t n, const float* x)
{
idx_t bs = 32768;
if (n > bs) {
for (idx_t i0 = 0; i0 < n; i0 += bs) {
idx_t i1 = std::min(i0 + bs, n);
if (verbose) {
printf("Index2Layer::add: adding %ld:%ld / %ld\n",
i0, i1, n);
}
add (i1 - i0, x + i0 * d);
}
return;
}
std::vector<idx_t> codes1 (n);
q1.quantizer->assign (n, x, codes1.data());
std::vector<float> residuals(n * d);
for (idx_t i = 0; i < n; i++) {
q1.quantizer->compute_residual (
x + i * d, residuals.data() + i * d, codes1[i]);
}
std::vector<uint8_t> codes2 (n * code_size_2);
pq.compute_codes (residuals.data(), codes2.data(), n);
codes.resize ((ntotal + n) * code_size);
uint8_t *wp = &codes[ntotal * code_size];
{
int i = 0x11223344;
const char *ip = (char*)&i;
FAISS_THROW_IF_NOT_MSG (ip[0] == 0x44,
"works only on a little-endian CPU");
}
// copy to output table
for (idx_t i = 0; i < n; i++) {
memcpy (wp, &codes1[i], code_size_1);
wp += code_size_1;
memcpy (wp, &codes2[i * code_size_2], code_size_2);
wp += code_size_2;
}
ntotal += n;
}
void Index2Layer::search(
idx_t /*n*/,
const float* /*x*/,
idx_t /*k*/,
float* /*distances*/,
idx_t* /*labels*/) const {
FAISS_THROW_MSG("not implemented");
}
void Index2Layer::reconstruct_n(idx_t i0, idx_t ni, float* recons) const
{
float recons1[d];
FAISS_THROW_IF_NOT (i0 >= 0 && i0 + ni <= ntotal);
const uint8_t *rp = &codes[i0 * code_size];
for (idx_t i = 0; i < ni; i++) {
idx_t key = 0;
memcpy (&key, rp, code_size_1);
q1.quantizer->reconstruct (key, recons1);
rp += code_size_1;
pq.decode (rp, recons);
for (idx_t j = 0; j < d; j++) {
recons[j] += recons1[j];
}
rp += code_size_2;
recons += d;
}
}
void Index2Layer::transfer_to_IVFPQ (IndexIVFPQ & other) const
{
FAISS_THROW_IF_NOT (other.nlist == q1.nlist);
FAISS_THROW_IF_NOT (other.code_size == code_size_2);
FAISS_THROW_IF_NOT (other.ntotal == 0);
const uint8_t *rp = codes.data();
for (idx_t i = 0; i < ntotal; i++) {
idx_t key = 0;
memcpy (&key, rp, code_size_1);
rp += code_size_1;
other.invlists->add_entry (key, i, rp);
rp += code_size_2;
}
other.ntotal = ntotal;
}
void Index2Layer::reconstruct(idx_t key, float* recons) const
{
reconstruct_n (key, 1, recons);
}
void Index2Layer::reset()
{
ntotal = 0;
codes.clear ();
}
namespace {
struct Distance2Level : DistanceComputer {
size_t d;
const Index2Layer& storage;
std::vector<float> buf;
const float *q;
const float *pq_l1_tab, *pq_l2_tab;
explicit Distance2Level(const Index2Layer& storage)
: storage(storage) {
d = storage.d;
FAISS_ASSERT(storage.pq.dsub == 4);
pq_l2_tab = storage.pq.centroids.data();
buf.resize(2 * d);
}
float symmetric_dis(idx_t i, idx_t j) override {
storage.reconstruct(i, buf.data());
storage.reconstruct(j, buf.data() + d);
return fvec_L2sqr(buf.data() + d, buf.data(), d);
}
void set_query(const float *x) override {
q = x;
}
};
// well optimized for xNN+PQNN
struct DistanceXPQ4 : Distance2Level {
int M, k;
explicit DistanceXPQ4(const Index2Layer& storage)
: Distance2Level (storage) {
const IndexFlat *quantizer =
dynamic_cast<IndexFlat*> (storage.q1.quantizer);
FAISS_ASSERT(quantizer);
M = storage.pq.M;
pq_l1_tab = quantizer->xb.data();
}
float operator () (idx_t i) override {
#ifdef __SSE__
const uint8_t *code = storage.codes.data() + i * storage.code_size;
long key = 0;
memcpy (&key, code, storage.code_size_1);
code += storage.code_size_1;
// walking pointers
const float *qa = q;
const __m128 *l1_t = (const __m128 *)(pq_l1_tab + d * key);
const __m128 *pq_l2_t = (const __m128 *)pq_l2_tab;
__m128 accu = _mm_setzero_ps();
for (int m = 0; m < M; m++) {
__m128 qi = _mm_loadu_ps(qa);
__m128 recons = l1_t[m] + pq_l2_t[*code++];
__m128 diff = qi - recons;
accu += diff * diff;
pq_l2_t += 256;
qa += 4;
}
accu = _mm_hadd_ps (accu, accu);
accu = _mm_hadd_ps (accu, accu);
return _mm_cvtss_f32 (accu);
#else
FAISS_THROW_MSG("not implemented for non-x64 platforms");
#endif
}
};
// well optimized for 2xNN+PQNN
struct Distance2xXPQ4 : Distance2Level {
int M_2, mi_nbits;
explicit Distance2xXPQ4(const Index2Layer& storage)
: Distance2Level(storage) {
const MultiIndexQuantizer *mi =
dynamic_cast<MultiIndexQuantizer*> (storage.q1.quantizer);
FAISS_ASSERT(mi);
FAISS_ASSERT(storage.pq.M % 2 == 0);
M_2 = storage.pq.M / 2;
mi_nbits = mi->pq.nbits;
pq_l1_tab = mi->pq.centroids.data();
}
float operator () (idx_t i) override {
const uint8_t *code = storage.codes.data() + i * storage.code_size;
long key01 = 0;
memcpy (&key01, code, storage.code_size_1);
code += storage.code_size_1;
#ifdef __SSE__
// walking pointers
const float *qa = q;
const __m128 *pq_l1_t = (const __m128 *)pq_l1_tab;
const __m128 *pq_l2_t = (const __m128 *)pq_l2_tab;
__m128 accu = _mm_setzero_ps();
for (int mi_m = 0; mi_m < 2; mi_m++) {
long l1_idx = key01 & ((1L << mi_nbits) - 1);
const __m128 * pq_l1 = pq_l1_t + M_2 * l1_idx;
for (int m = 0; m < M_2; m++) {
__m128 qi = _mm_loadu_ps(qa);
__m128 recons = pq_l1[m] + pq_l2_t[*code++];
__m128 diff = qi - recons;
accu += diff * diff;
pq_l2_t += 256;
qa += 4;
}
pq_l1_t += M_2 << mi_nbits;
key01 >>= mi_nbits;
}
accu = _mm_hadd_ps (accu, accu);
accu = _mm_hadd_ps (accu, accu);
return _mm_cvtss_f32 (accu);
#else
FAISS_THROW_MSG("not implemented for non-x64 platforms");
#endif
}
};
} // namespace
DistanceComputer * Index2Layer::get_distance_computer() const {
#ifdef __SSE__
const MultiIndexQuantizer *mi =
dynamic_cast<MultiIndexQuantizer*> (q1.quantizer);
if (mi && pq.M % 2 == 0 && pq.dsub == 4) {
return new Distance2xXPQ4(*this);
}
const IndexFlat *fl =
dynamic_cast<IndexFlat*> (q1.quantizer);
if (fl && pq.dsub == 4) {
return new DistanceXPQ4(*this);
}
#endif
return Index::get_distance_computer();
}
/* The standalone codec interface */
size_t Index2Layer::sa_code_size () const
{
return code_size;
}
void Index2Layer::sa_encode (idx_t n, const float *x, uint8_t *bytes) const
{
FAISS_THROW_IF_NOT (is_trained);
std::unique_ptr<int64_t []> list_nos (new int64_t [n]);
q1.quantizer->assign (n, x, list_nos.get());
std::vector<float> residuals(n * d);
for (idx_t i = 0; i < n; i++) {
q1.quantizer->compute_residual (
x + i * d, residuals.data() + i * d, list_nos[i]);
}
pq.compute_codes (residuals.data(), bytes, n);
for (idx_t i = n - 1; i >= 0; i--) {
uint8_t * code = bytes + i * code_size;
memmove (code + code_size_1,
bytes + i * code_size_2, code_size_2);
q1.encode_listno (list_nos[i], code);
}
}
void Index2Layer::sa_decode (idx_t n, const uint8_t *bytes, float *x) const
{
#pragma omp parallel
{
std::vector<float> residual (d);
#pragma omp for
for (size_t i = 0; i < n; i++) {
const uint8_t *code = bytes + i * code_size;
int64_t list_no = q1.decode_listno (code);
float *xi = x + i * d;
pq.decode (code + code_size_1, xi);
q1.quantizer->reconstruct (list_no, residual.data());
for (size_t j = 0; j < d; j++) {
xi[j] += residual[j];
}
}
}
}
} // namespace faiss