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block_posting_list.hpp
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#pragma once
#include "succinct/util.hpp"
#include "block_codecs.hpp"
#include "util.hpp"
namespace quasi_succinct {
template <typename BlockCodec>
struct block_posting_list {
template <typename DocsIterator, typename FreqsIterator>
static void write(std::vector<uint8_t>& out, uint32_t n,
DocsIterator docs_begin, FreqsIterator freqs_begin) {
TightVariableByte::encode_single(n, out);
uint64_t block_size = BlockCodec::block_size;
uint64_t blocks = succinct::util::ceil_div(n, block_size);
size_t begin_block_maxs = out.size();
size_t begin_block_endpoints = begin_block_maxs + 4 * blocks;
size_t begin_blocks = begin_block_endpoints + 4 * (blocks - 1);
out.resize(begin_blocks);
DocsIterator docs_it(docs_begin);
FreqsIterator freqs_it(freqs_begin);
std::vector<uint32_t> docs_buf(block_size);
std::vector<uint32_t> freqs_buf(block_size);
uint32_t last_doc(-1);
uint32_t block_base = 0;
for (size_t b = 0; b < blocks; ++b) {
uint32_t cur_block_size =
((b + 1) * block_size <= n)
? block_size : (n % block_size);
for (size_t i = 0; i < cur_block_size; ++i) {
uint32_t doc(*docs_it++);
docs_buf[i] = doc - last_doc - 1;
last_doc = doc;
freqs_buf[i] = *freqs_it++ - 1;
}
*((uint32_t*)&out[begin_block_maxs + 4 * b]) = last_doc;
BlockCodec::encode(docs_buf.data(), last_doc - block_base - (cur_block_size - 1),
cur_block_size, out);
BlockCodec::encode(freqs_buf.data(), uint32_t(-1), cur_block_size, out);
if (b != blocks - 1) {
*((uint32_t*)&out[begin_block_endpoints + 4 * b]) = out.size() - begin_blocks;
}
block_base = last_doc + 1;
}
}
class document_enumerator {
public:
document_enumerator(uint8_t const* data, uint64_t universe)
: m_n(0) // just to silence warnings
, m_base(TightVariableByte::decode(data, &m_n, 1))
, m_blocks(succinct::util::ceil_div(m_n, BlockCodec::block_size))
, m_block_maxs(m_base)
, m_block_endpoints(m_block_maxs + 4 * m_blocks)
, m_blocks_data(m_block_endpoints + 4 * (m_blocks - 1))
, m_universe(universe)
{
m_docs_buf.resize(BlockCodec::block_size);
m_freqs_buf.resize(BlockCodec::block_size);
reset();
}
void reset()
{
decode_docs_block(0);
}
void QS_ALWAYSINLINE next()
{
++m_pos_in_block;
if (QS_UNLIKELY(m_pos_in_block == m_cur_block_size)) {
if (m_cur_block + 1 == m_blocks) {
m_cur_docid = m_universe;
return;
}
decode_docs_block(m_cur_block + 1);
} else {
m_cur_docid += m_docs_buf[m_pos_in_block] + 1;
}
}
void QS_ALWAYSINLINE next_geq(uint64_t lower_bound)
{
assert(lower_bound >= m_cur_docid);
if (QS_UNLIKELY(lower_bound > m_cur_block_max)) {
// binary search seems to perform worse here
if (lower_bound > block_max(m_blocks - 1)) {
m_cur_docid = m_universe;
return;
}
uint64_t block = m_cur_block + 1;
while (block_max(block) < lower_bound) {
++block;
}
decode_docs_block(block);
}
while (docid() < lower_bound) {
m_cur_docid += m_docs_buf[++m_pos_in_block] + 1;
assert(m_pos_in_block < m_cur_block_size);
}
}
void QS_ALWAYSINLINE move(uint64_t pos)
{
assert(pos >= position());
uint64_t block = pos / BlockCodec::block_size;
if (QS_UNLIKELY(block != m_cur_block)) {
decode_docs_block(block);
}
while (position() < pos) {
m_cur_docid += m_docs_buf[++m_pos_in_block] + 1;
}
}
uint64_t docid() const
{
return m_cur_docid;
}
uint64_t QS_ALWAYSINLINE freq()
{
if (!m_freqs_decoded) {
decode_freqs_block();
}
return m_freqs_buf[m_pos_in_block] + 1;
}
uint64_t position() const
{
return m_cur_block * BlockCodec::block_size + m_pos_in_block;
}
uint64_t size() const
{
return m_n;
}
uint64_t stats_freqs_size() const
{
uint64_t bytes = 0;
uint8_t const* ptr = m_blocks_data;
static const uint64_t block_size = BlockCodec::block_size;
std::vector<uint32_t> buf(block_size);
for (size_t b = 0; b < m_blocks; ++b) {
uint32_t cur_block_size =
((b + 1) * block_size <= size())
? block_size : (size() % block_size);
uint32_t cur_base = (b ? block_max(b - 1) : uint32_t(-1)) + 1;
uint8_t const* freq_ptr =
BlockCodec::decode(ptr, buf.data(),
block_max(b) - cur_base - (cur_block_size - 1),
cur_block_size);
ptr = BlockCodec::decode(freq_ptr, buf.data(),
uint32_t(-1), cur_block_size);
bytes += ptr - freq_ptr;
}
return bytes;
}
private:
uint32_t block_max(uint32_t block) const
{
return ((uint32_t const*)m_block_maxs)[block];
}
void QS_NOINLINE decode_docs_block(uint64_t block)
{
static const uint64_t block_size = BlockCodec::block_size;
uint32_t endpoint = block
? ((uint32_t const*)m_block_endpoints)[block - 1]
: 0;
uint8_t const* block_data = m_blocks_data + endpoint;
m_cur_block_size =
((block + 1) * block_size <= size())
? block_size : (size() % block_size);
uint32_t cur_base = (block ? block_max(block - 1) : uint32_t(-1)) + 1;
m_cur_block_max = block_max(block);
m_freqs_block_data =
BlockCodec::decode(block_data, m_docs_buf.data(),
m_cur_block_max - cur_base - (m_cur_block_size - 1),
m_cur_block_size);
m_docs_buf[0] += cur_base;
m_cur_block = block;
m_pos_in_block = 0;
m_cur_docid = m_docs_buf[0];
m_freqs_decoded = false;
}
void QS_NOINLINE decode_freqs_block()
{
BlockCodec::decode(m_freqs_block_data, m_freqs_buf.data(),
uint32_t(-1), m_cur_block_size);
m_freqs_decoded = true;
}
uint32_t m_n;
uint8_t const* m_base;
uint32_t m_blocks;
uint8_t const* m_block_maxs;
uint8_t const* m_block_endpoints;
uint8_t const* m_blocks_data;
uint64_t m_universe;
uint32_t m_cur_block;
uint32_t m_pos_in_block;
uint32_t m_cur_block_max;
uint32_t m_cur_block_size;
uint32_t m_cur_docid;
uint8_t const* m_freqs_block_data;
bool m_freqs_decoded;
std::vector<uint32_t> m_docs_buf;
std::vector<uint32_t> m_freqs_buf;
};
};
}