63 const std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,
65 const unsigned block_size,
66 const unsigned grid_size)
68 , device_type_(device_type)
70 , query_mem_desc_(query_mem_desc)
71 , crt_row_buff_idx_(0)
75 , row_set_mem_owner_(row_set_mem_owner)
77 , block_size_(block_size)
78 , grid_size_(grid_size)
80 , separate_varlen_storage_valid_(
false)
81 , just_explain_(
false)
82 , for_validation_only_(
false)
83 , cached_row_count_(-1)
87 const std::vector<ColumnLazyFetchInfo>& lazy_fetch_info,
88 const std::vector<std::vector<const int8_t*>>& col_buffers,
89 const std::vector<std::vector<int64_t>>& frag_offsets,
90 const std::vector<int64_t>& consistent_frag_sizes,
94 const std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,
96 const unsigned block_size,
97 const unsigned grid_size)
99 , device_type_(device_type)
100 , device_id_(device_id)
101 , query_mem_desc_(query_mem_desc)
102 , crt_row_buff_idx_(0)
106 , row_set_mem_owner_(row_set_mem_owner)
108 , block_size_(block_size)
109 , grid_size_(grid_size)
110 , lazy_fetch_info_(lazy_fetch_info)
111 , col_buffers_{col_buffers}
112 , frag_offsets_{frag_offsets}
113 , consistent_frag_sizes_{consistent_frag_sizes}
115 , separate_varlen_storage_valid_(
false)
116 , just_explain_(
false)
117 , for_validation_only_(
false)
118 , cached_row_count_(-1)
119 , geo_return_type_(GeoReturnType::WktString) {}
125 : device_type_(device_type)
126 , device_id_(device_id)
128 , crt_row_buff_idx_(0)
129 , estimator_(estimator)
130 , data_mgr_(data_mgr)
131 , separate_varlen_storage_valid_(
false)
132 , just_explain_(
false)
133 , for_validation_only_(
false)
134 , cached_row_count_(-1)
135 , geo_return_type_(GeoReturnType::WktString) {
138 data_mgr_, estimator_->getBufferSize(), device_id_);
139 data_mgr->getCudaMgr()->zeroDeviceMem(device_estimator_buffer_->getMemoryPtr(),
140 estimator_->getBufferSize(),
143 host_estimator_buffer_ =
144 static_cast<int8_t*
>(
checked_calloc(estimator_->getBufferSize(), 1));
152 , separate_varlen_storage_valid_(
false)
153 , explanation_(explanation)
154 , just_explain_(
true)
155 , for_validation_only_(
false)
156 , cached_row_count_(-1)
160 int64_t render_time_ms,
161 const std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner)
165 , row_set_mem_owner_(row_set_mem_owner)
167 , separate_varlen_storage_valid_(
false)
168 , just_explain_(
true)
169 , for_validation_only_(
false)
170 , cached_row_count_(-1)
171 , geo_return_type_(GeoReturnType::WktString){};
175 if (!storage_->buff_is_provided_) {
176 CHECK(storage_->getUnderlyingBuffer());
177 free(storage_->getUnderlyingBuffer());
180 for (
auto& storage : appended_storage_) {
181 if (storage && !storage->buff_is_provided_) {
182 free(storage->getUnderlyingBuffer());
185 if (host_estimator_buffer_) {
187 free(host_estimator_buffer_);
189 if (device_estimator_buffer_) {
191 data_mgr_->free(device_estimator_buffer_);
201 CHECK(row_set_mem_owner_);
202 auto buff = row_set_mem_owner_->allocate(
203 query_mem_desc_.getBufferSizeBytes(device_type_), 0);
206 return storage_.get();
211 const std::vector<int64_t>& target_init_vals)
const {
214 storage_.reset(
new ResultSetStorage(targets_, query_mem_desc_, buff,
true));
215 storage_->target_init_vals_ = target_init_vals;
216 return storage_.get();
220 const std::vector<int64_t>& target_init_vals)
const {
222 CHECK(row_set_mem_owner_);
223 auto buff = row_set_mem_owner_->allocate(
224 query_mem_desc_.getBufferSizeBytes(device_type_), 0);
227 storage_->target_init_vals_ = target_init_vals;
228 return storage_.get();
232 if (crt_row_buff_idx_ == 0) {
233 throw std::runtime_error(
"current row buffer iteration index is undefined");
235 return crt_row_buff_idx_ - 1;
241 if (!that.storage_) {
244 appended_storage_.push_back(std::move(that.storage_));
245 query_mem_desc_.setEntryCount(
246 query_mem_desc_.getEntryCount() +
247 appended_storage_.back()->query_mem_desc_.getEntryCount());
248 chunks_.insert(chunks_.end(), that.chunks_.begin(), that.chunks_.end());
250 col_buffers_.end(), that.col_buffers_.begin(), that.col_buffers_.end());
251 frag_offsets_.insert(
252 frag_offsets_.end(), that.frag_offsets_.begin(), that.frag_offsets_.end());
253 consistent_frag_sizes_.insert(consistent_frag_sizes_.end(),
254 that.consistent_frag_sizes_.begin(),
255 that.consistent_frag_sizes_.end());
257 chunk_iters_.end(), that.chunk_iters_.begin(), that.chunk_iters_.end());
258 if (separate_varlen_storage_valid_) {
259 CHECK(that.separate_varlen_storage_valid_);
260 serialized_varlen_buffer_.insert(serialized_varlen_buffer_.end(),
261 that.serialized_varlen_buffer_.begin(),
262 that.serialized_varlen_buffer_.end());
264 for (
auto& buff : that.literal_buffers_) {
265 literal_buffers_.push_back(std::move(buff));
270 return storage_.get();
274 return just_explain_ ? 1 : targets_.size();
283 : targets_[col_idx].sql_type;
289 if (total_row_count < offset) {
293 size_t total_truncated_row_count = total_row_count - offset;
296 return std::min(total_truncated_row_count, limit);
299 return total_truncated_row_count;
308 if (!permutation_.empty()) {
309 if (drop_first_ > permutation_.size()) {
312 const auto limited_row_count = keep_first_ + drop_first_;
313 return limited_row_count ? std::min(limited_row_count, permutation_.size())
314 : permutation_.size();
316 if (cached_row_count_ != -1) {
318 return cached_row_count_;
323 if (permutation_.empty() &&
325 return binSearchRowCount();
327 if (force_parallel || entryCount() > 20000) {
328 return parallelRowCount();
330 std::lock_guard<std::mutex> lock(row_iteration_mutex_);
334 auto crt_row = getNextRowUnlocked(
false,
false);
335 if (crt_row.empty()) {
345 CHECK(cached_row_count_ == -1 || cached_row_count_ == static_cast<int64_t>(row_count));
346 cached_row_count_ = row_count;
354 size_t row_count = storage_->binSearchRowCount();
355 for (
auto& s : appended_storage_) {
356 row_count += s->binSearchRowCount();
363 auto execute_parallel_row_count = [
this](
auto counter_threads) ->
size_t {
367 stride = (entryCount() + worker_count - 1) / worker_count;
368 i < worker_count && start_entry < entryCount();
369 ++
i, start_entry += stride) {
370 const auto end_entry = std::min(start_entry + stride, entryCount());
371 counter_threads.spawn(
372 [
this](
const size_t start,
const size_t end) {
374 for (
size_t i = start;
i < end; ++
i) {
375 if (!isRowAtEmpty(
i)) {
384 const auto row_counts = counter_threads.join();
385 const size_t row_count =
std::accumulate(row_counts.begin(), row_counts.end(), 0);
389 const auto row_count =
398 return !storage_ && !estimator_ && !just_explain_;
403 return storage_->query_mem_desc_;
412 return storage_->target_init_vals_;
417 CHECK(device_estimator_buffer_);
418 return device_estimator_buffer_->getMemoryPtr();
422 return host_estimator_buffer_;
427 CHECK(!host_estimator_buffer_);
428 CHECK_EQ(
size_t(0), estimator_->getBufferSize() %
sizeof(int64_t));
429 host_estimator_buffer_ =
430 static_cast<int8_t*
>(
checked_calloc(estimator_->getBufferSize(), 1));
431 CHECK(device_estimator_buffer_);
432 auto device_buffer_ptr = device_estimator_buffer_->getMemoryPtr();
434 host_estimator_buffer_,
435 reinterpret_cast<CUdeviceptr>(device_buffer_ptr),
436 estimator_->getBufferSize(),
441 timings_.executor_queue_time = queue_time;
445 timings_.kernel_queue_time = kernel_queue_time;
449 timings_.compilation_queue_time += compilation_queue_time;
453 return timings_.executor_queue_time + timings_.kernel_queue_time +
454 timings_.compilation_queue_time;
458 return timings_.render_time;
462 crt_row_buff_idx_ = 0;
467 return keep_first_ + drop_first_;
471 return just_explain_;
475 for_validation_only_ =
true;
479 return for_validation_only_;
489 query_mem_desc_copy.resetGroupColWidths(
490 std::vector<int8_t>(query_mem_desc_copy.getGroupbyColCount(), 8));
492 return query_mem_desc_copy;
494 query_mem_desc_copy.alignPaddedSlots();
495 return query_mem_desc_copy;
500 const Executor* executor) {
507 CHECK(!targets_.empty());
509 if (canUseFastBaselineSort(order_entries, top_n)) {
510 baselineSort(order_entries, top_n, executor);
514 if (query_mem_desc_.sortOnGpu()) {
516 radixSortOnGpu(order_entries);
518 LOG(
WARNING) <<
"Out of GPU memory during sort, finish on CPU";
519 radixSortOnCpu(order_entries);
520 }
catch (
const std::bad_alloc&) {
521 LOG(
WARNING) <<
"Out of GPU memory during sort, finish on CPU";
522 radixSortOnCpu(order_entries);
527 if (query_mem_desc_.getEntryCount() > std::numeric_limits<uint32_t>::max()) {
531 CHECK(permutation_.empty());
537 parallelTop(order_entries, top_n, executor);
542 permutation_.resize(query_mem_desc_.getEntryCount());
545 pv = initPermutationBuffer(pv, 0, permutation_.size());
549 pv = topPermutation(pv, top_n, createComparator(order_entries, pv, executor,
false));
550 if (pv.size() < permutation_.size()) {
551 permutation_.resize(pv.size());
552 permutation_.shrink_to_fit();
560 const Executor* executor) {
563 if (getGpuCount() > 1) {
581 const auto storage_lookup_result = findStorage(
i);
582 const auto lhs_storage = storage_lookup_result.storage_ptr;
583 const auto off = storage_lookup_result.fixedup_entry_idx;
585 if (!lhs_storage->isEmptyEntry(off)) {
598 const Executor* executor) {
603 permutation_.resize(query_mem_desc_.getEntryCount());
604 std::vector<PermutationView> permutation_views(nthreads);
605 const auto top_sort_interval = [&, top_n, executor](
const auto interval) {
606 PermutationView pv(permutation_.data() + interval.begin, 0, interval.size());
607 pv = initPermutationBuffer(pv, interval.begin, interval.end);
608 const auto compare = createComparator(order_entries, pv, executor,
true);
609 permutation_views[interval.index] = topPermutation(pv, top_n, compare);
612 for (
auto interval : makeIntervals<PermutationIdx>(0, permutation_.size(), nthreads)) {
613 top_sort_threads.
spawn(top_sort_interval, interval);
615 top_sort_threads.
join();
624 auto end = permutation_.begin() + permutation_views.front().size();
625 for (
size_t i = 1;
i < nthreads; ++
i) {
626 std::copy(permutation_views[
i].begin(), permutation_views[
i].end(), end);
627 end += permutation_views[
i].size();
632 const auto compare = createComparator(order_entries, pv, executor,
false);
633 pv = topPermutation(pv, top_n, compare);
634 permutation_.resize(pv.size());
635 permutation_.shrink_to_fit();
639 size_t fixedup_entry_idx = entry_idx;
640 auto entry_count = storage_->query_mem_desc_.getEntryCount();
641 const bool is_rowwise_layout = !storage_->query_mem_desc_.didOutputColumnar();
642 if (fixedup_entry_idx < entry_count) {
643 return {0, fixedup_entry_idx};
645 fixedup_entry_idx -= entry_count;
646 for (
size_t i = 0;
i < appended_storage_.size(); ++
i) {
647 const auto& desc = appended_storage_[
i]->query_mem_desc_;
648 CHECK_NE(is_rowwise_layout, desc.didOutputColumnar());
649 entry_count = desc.getEntryCount();
650 if (fixedup_entry_idx < entry_count) {
651 return {
i + 1, fixedup_entry_idx};
653 fixedup_entry_idx -= entry_count;
655 UNREACHABLE() <<
"entry_idx = " << entry_idx <<
", query_mem_desc_.getEntryCount() = "
656 << query_mem_desc_.getEntryCount();
664 auto [stg_idx, fixedup_entry_idx] = getStorageIndex(entry_idx);
665 return {stg_idx ? appended_storage_[stg_idx - 1].get() : storage_.get(),
670 template <
typename BUFFER_ITERATOR_TYPE>
672 BUFFER_ITERATOR_TYPE>::materializeCountDistinctColumns() {
673 for (
const auto& order_entry : order_entries_) {
675 count_distinct_materialized_buffers_.emplace_back(
676 materializeCountDistinctColumn(order_entry));
681 template <
typename BUFFER_ITERATOR_TYPE>
683 BUFFER_ITERATOR_TYPE>::materializeApproxMedianColumns()
const {
685 for (
const auto& order_entry : order_entries_) {
686 if (result_set_->targets_[order_entry.tle_no - 1].agg_kind ==
kAPPROX_MEDIAN) {
687 approx_median_materialized_buffers.emplace_back(
688 materializeApproxMedianColumn(order_entry));
691 return approx_median_materialized_buffers;
694 template <
typename BUFFER_ITERATOR_TYPE>
698 const size_t num_storage_entries = result_set_->query_mem_desc_.getEntryCount();
699 std::vector<int64_t> count_distinct_materialized_buffer(num_storage_entries);
701 result_set_->query_mem_desc_.getCountDistinctDescriptor(order_entry.
tle_no - 1);
702 const size_t num_non_empty_entries = permutation_.size();
703 const auto work = [&](
const size_t start,
const size_t end) {
704 for (
size_t i = start;
i < end; ++
i) {
706 const auto storage_lookup_result = result_set_->findStorage(permuted_idx);
707 const auto storage = storage_lookup_result.storage_ptr;
708 const auto off = storage_lookup_result.fixedup_entry_idx;
709 const auto value = buffer_itr_.getColumnInternal(
710 storage->buff_, off, order_entry.
tle_no - 1, storage_lookup_result);
711 count_distinct_materialized_buffer[permuted_idx] =
717 if (single_threaded_) {
718 work(0, num_non_empty_entries);
721 for (
auto interval : makeIntervals<size_t>(0, num_non_empty_entries,
cpu_threads())) {
722 thread_pool.
spawn(work, interval.begin, interval.end);
726 return count_distinct_materialized_buffer;
731 CHECK(t_digest) <<
"t_digest=" << (
void*)t_digest <<
", q=" << q;
733 double const median = t_digest->
quantile(q);
734 return boost::math::isnan(median) ?
NULL_DOUBLE : median;
737 template <
typename BUFFER_ITERATOR_TYPE>
738 ResultSet::ApproxMedianBuffers::value_type
741 ResultSet::ApproxMedianBuffers::value_type materialized_buffer(
742 result_set_->query_mem_desc_.getEntryCount());
743 const size_t size = permutation_.size();
744 const auto work = [&](
const size_t start,
const size_t end) {
745 for (
size_t i = start;
i < end; ++
i) {
747 const auto storage_lookup_result = result_set_->findStorage(permuted_idx);
748 const auto storage = storage_lookup_result.storage_ptr;
749 const auto off = storage_lookup_result.fixedup_entry_idx;
750 const auto value = buffer_itr_.getColumnInternal(
751 storage->buff_, off, order_entry.
tle_no - 1, storage_lookup_result);
752 materialized_buffer[permuted_idx] =
754 ? calculateQuantile(reinterpret_cast<quantile::TDigest*>(value.i1), 0.5)
758 if (single_threaded_) {
762 for (
auto interval : makeIntervals<size_t>(0, size,
cpu_threads())) {
763 thread_pool.
spawn(work, interval.begin, interval.end);
767 return materialized_buffer;
770 template <
typename BUFFER_ITERATOR_TYPE>
776 const auto lhs_storage_lookup_result = result_set_->findStorage(lhs);
777 const auto rhs_storage_lookup_result = result_set_->findStorage(rhs);
778 const auto lhs_storage = lhs_storage_lookup_result.storage_ptr;
779 const auto rhs_storage = rhs_storage_lookup_result.storage_ptr;
780 const auto fixedup_lhs = lhs_storage_lookup_result.fixedup_entry_idx;
781 const auto fixedup_rhs = rhs_storage_lookup_result.fixedup_entry_idx;
782 size_t materialized_count_distinct_buffer_idx{0};
783 size_t materialized_approx_median_buffer_idx{0};
785 for (
const auto& order_entry : order_entries_) {
787 const auto& agg_info = result_set_->targets_[order_entry.tle_no - 1];
795 if (entry_ti.get_type() ==
kFLOAT) {
796 const auto is_col_lazy =
797 !result_set_->lazy_fetch_info_.empty() &&
798 result_set_->lazy_fetch_info_[order_entry.tle_no - 1].is_lazily_fetched;
799 if (result_set_->query_mem_desc_.getPaddedSlotWidthBytes(order_entry.tle_no - 1) ==
801 float_argument_input =
802 result_set_->query_mem_desc_.didOutputColumnar() ? !is_col_lazy :
true;
807 CHECK_LT(materialized_count_distinct_buffer_idx,
808 count_distinct_materialized_buffers_.size());
810 const auto& count_distinct_materialized_buffer =
811 count_distinct_materialized_buffers_[materialized_count_distinct_buffer_idx];
812 const auto lhs_sz = count_distinct_materialized_buffer[lhs];
813 const auto rhs_sz = count_distinct_materialized_buffer[rhs];
814 ++materialized_count_distinct_buffer_idx;
815 if (lhs_sz == rhs_sz) {
818 return (lhs_sz < rhs_sz) != order_entry.is_desc;
820 CHECK_LT(materialized_approx_median_buffer_idx,
821 approx_median_materialized_buffers_.size());
822 const auto& approx_median_materialized_buffer =
823 approx_median_materialized_buffers_[materialized_approx_median_buffer_idx];
824 const auto lhs_value = approx_median_materialized_buffer[lhs];
825 const auto rhs_value = approx_median_materialized_buffer[rhs];
826 ++materialized_approx_median_buffer_idx;
827 if (lhs_value == rhs_value) {
829 }
else if (!entry_ti.get_notnull()) {
831 return order_entry.nulls_first;
833 return !order_entry.nulls_first;
836 return (lhs_value < rhs_value) != order_entry.is_desc;
839 const auto lhs_v = buffer_itr_.getColumnInternal(lhs_storage->buff_,
841 order_entry.tle_no - 1,
842 lhs_storage_lookup_result);
843 const auto rhs_v = buffer_itr_.getColumnInternal(rhs_storage->buff_,
845 order_entry.tle_no - 1,
846 rhs_storage_lookup_result);
848 if (
UNLIKELY(isNull(entry_ti, lhs_v, float_argument_input) &&
849 isNull(entry_ti, rhs_v, float_argument_input))) {
852 if (
UNLIKELY(isNull(entry_ti, lhs_v, float_argument_input) &&
853 !isNull(entry_ti, rhs_v, float_argument_input))) {
854 return order_entry.nulls_first;
856 if (
UNLIKELY(isNull(entry_ti, rhs_v, float_argument_input) &&
857 !isNull(entry_ti, lhs_v, float_argument_input))) {
858 return !order_entry.nulls_first;
861 if (
LIKELY(lhs_v.isInt())) {
862 CHECK(rhs_v.isInt());
863 if (
UNLIKELY(entry_ti.is_string() &&
865 CHECK_EQ(4, entry_ti.get_logical_size());
867 const auto string_dict_proxy = executor_->getStringDictionaryProxy(
868 entry_ti.get_comp_param(), result_set_->row_set_mem_owner_,
false);
869 auto lhs_str = string_dict_proxy->getString(lhs_v.i1);
870 auto rhs_str = string_dict_proxy->getString(rhs_v.i1);
871 if (lhs_str == rhs_str) {
874 return (lhs_str < rhs_str) != order_entry.is_desc;
877 if (lhs_v.i1 == rhs_v.i1) {
880 if (entry_ti.is_fp()) {
881 if (float_argument_input) {
882 const auto lhs_dval = *
reinterpret_cast<const float*
>(may_alias_ptr(&lhs_v.i1));
883 const auto rhs_dval = *
reinterpret_cast<const float*
>(may_alias_ptr(&rhs_v.i1));
884 return (lhs_dval < rhs_dval) != order_entry.is_desc;
886 const auto lhs_dval =
887 *
reinterpret_cast<const double*
>(may_alias_ptr(&lhs_v.i1));
888 const auto rhs_dval =
889 *
reinterpret_cast<const double*
>(may_alias_ptr(&rhs_v.i1));
890 return (lhs_dval < rhs_dval) != order_entry.is_desc;
893 return (lhs_v.i1 < rhs_v.i1) != order_entry.is_desc;
895 if (lhs_v.isPair()) {
896 CHECK(rhs_v.isPair());
898 pair_to_double({lhs_v.i1, lhs_v.i2}, entry_ti, float_argument_input);
900 pair_to_double({rhs_v.i1, rhs_v.i2}, entry_ti, float_argument_input);
904 return (lhs < rhs) != order_entry.is_desc;
906 CHECK(lhs_v.isStr() && rhs_v.isStr());
907 const auto lhs = lhs_v.strVal();
908 const auto rhs = rhs_v.strVal();
912 return (lhs < rhs) != order_entry.is_desc;
926 if (n < permutation.
size()) {
928 permutation.
begin(), permutation.
begin() + n, permutation.
end(), compare);
937 const std::list<Analyzer::OrderEntry>& order_entries)
const {
939 auto data_mgr = &
catalog_->getDataMgr();
940 const int device_id{0};
944 std::vector<int64_t*> group_by_buffers(block_size_);
945 group_by_buffers[0] =
reinterpret_cast<int64_t*
>(storage_->getUnderlyingBuffer());
946 auto dev_group_by_buffers =
960 order_entries, query_mem_desc_, dev_group_by_buffers, data_mgr, device_id);
965 dev_group_by_buffers.second,
974 const std::list<Analyzer::OrderEntry>& order_entries)
const {
976 CHECK(!query_mem_desc_.hasKeylessHash());
977 std::vector<int64_t> tmp_buff(query_mem_desc_.getEntryCount());
978 std::vector<int32_t> idx_buff(query_mem_desc_.getEntryCount());
979 CHECK_EQ(
size_t(1), order_entries.size());
980 auto buffer_ptr = storage_->getUnderlyingBuffer();
981 for (
const auto& order_entry : order_entries) {
982 const auto target_idx = order_entry.tle_no - 1;
983 const auto sortkey_val_buff =
reinterpret_cast<int64_t*
>(
984 buffer_ptr + query_mem_desc_.getColOffInBytes(target_idx));
985 const auto chosen_bytes = query_mem_desc_.getPaddedSlotWidthBytes(target_idx);
988 query_mem_desc_.getEntryCount(),
993 query_mem_desc_.getEntryCount(),
996 for (
size_t target_idx = 0; target_idx < query_mem_desc_.getSlotCount();
998 if (static_cast<int>(target_idx) == order_entry.tle_no - 1) {
1001 const auto chosen_bytes = query_mem_desc_.getPaddedSlotWidthBytes(target_idx);
1002 const auto satellite_val_buff =
reinterpret_cast<int64_t*
>(
1003 buffer_ptr + query_mem_desc_.getColOffInBytes(target_idx));
1006 query_mem_desc_.getEntryCount(),
1018 const int dict_id)
const {
1019 const auto sdp = row_set_mem_owner_->getOrAddStringDictProxy(
1022 return sdp->getDictionary()->copyStrings();
1035 }
else if (query_mem_desc_.didOutputColumnar()) {
1036 return permutation_.empty() && (query_mem_desc_.getQueryDescriptionType() ==
1038 (query_mem_desc_.getQueryDescriptionType() ==
1040 query_mem_desc_.getQueryDescriptionType() ==
1043 return permutation_.empty() && (query_mem_desc_.getQueryDescriptionType() ==
1045 query_mem_desc_.getQueryDescriptionType() ==
1051 return query_mem_desc_.didOutputColumnar() &&
1053 appended_storage_.empty() && storage_ &&
1054 (lazy_fetch_info_.empty() || !lazy_fetch_info_[column_idx].is_lazily_fetched);
1058 CHECK(isZeroCopyColumnarConversionPossible(column_idx));
1059 return storage_->getUnderlyingBuffer() + query_mem_desc_.getColOffInBytes(column_idx);
1064 std::vector<bool> target_bitmap(targets_.size(),
true);
1065 size_t num_single_slot_targets = 0;
1066 for (
size_t target_idx = 0; target_idx < targets_.size(); target_idx++) {
1067 const auto& sql_type = targets_[target_idx].sql_type;
1068 if (targets_[target_idx].
is_agg && targets_[target_idx].agg_kind ==
kAVG) {
1069 target_bitmap[target_idx] =
false;
1070 }
else if (sql_type.is_varlen()) {
1071 target_bitmap[target_idx] =
false;
1073 num_single_slot_targets++;
1076 return std::make_tuple(std::move(target_bitmap), num_single_slot_targets);
1089 CHECK(isDirectColumnarConversionPossible());
1090 auto [single_slot_targets, num_single_slot_targets] = getSingleSlotTargetBitmap();
1092 for (
size_t target_idx = 0; target_idx < single_slot_targets.size(); target_idx++) {
1093 const auto& target = targets_[target_idx];
1094 if (single_slot_targets[target_idx] &&
1096 (target.is_agg && target.agg_kind ==
kSAMPLE && target.sql_type ==
kFLOAT))) {
1097 single_slot_targets[target_idx] =
false;
1098 num_single_slot_targets--;
1101 CHECK_GE(num_single_slot_targets,
size_t(0));
1102 return std::make_tuple(std::move(single_slot_targets), num_single_slot_targets);
1107 std::vector<size_t> slot_indices(targets_.size(), 0);
1108 size_t slot_index = 0;
1109 for (
size_t target_idx = 0; target_idx < targets_.size(); target_idx++) {
1110 slot_indices[target_idx] = slot_index;
1111 slot_index =
advance_slot(slot_index, targets_[target_idx],
false);
1113 return slot_indices;
1119 return !rows.isTruncated();
bool is_agg(const Analyzer::Expr *expr)
void syncEstimatorBuffer() const
const QueryMemoryDescriptor & getQueryMemDesc() const
void sort_groups_cpu(int64_t *val_buff, int32_t *idx_buff, const uint64_t entry_count, const bool desc, const uint32_t chosen_bytes)
size_t g_parallel_top_max
std::pair< size_t, size_t > getStorageIndex(const size_t entry_idx) const
DEVICE void push_back(T const &value)
bool isValidationOnlyRes() const
void setValidationOnlyRes()
PermutationView initPermutationBuffer(PermutationView permutation, PermutationIdx const begin, PermutationIdx const end) const
DEVICE RealType quantile(RealType const q)
class for a per-database catalog. also includes metadata for the current database and the current use...
GpuGroupByBuffers create_dev_group_by_buffers(DeviceAllocator *cuda_allocator, const std::vector< int64_t * > &group_by_buffers, const QueryMemoryDescriptor &query_mem_desc, const unsigned block_size_x, const unsigned grid_size_x, const int device_id, const ExecutorDispatchMode dispatch_mode, const int64_t num_input_rows, const bool prepend_index_buffer, const bool always_init_group_by_on_host, const bool use_bump_allocator, Allocator *insitu_allocator)
bool g_enable_direct_columnarization
static const size_t baseline_threshold
ResultSet(const std::vector< TargetInfo > &targets, const ExecutorDeviceType device_type, const QueryMemoryDescriptor &query_mem_desc, const std::shared_ptr< RowSetMemoryOwner > row_set_mem_owner, const Catalog_Namespace::Catalog *catalog, const unsigned block_size, const unsigned grid_size)
DEVICE void sort(ARGS &&...args)
const std::vector< TargetInfo > & getTargetInfos() const
void setKernelQueueTime(const int64_t kernel_queue_time)
size_t rowCount(const bool force_parallel=false) const
DEVICE void mergeBuffer()
void keepFirstN(const size_t n)
double pair_to_double(const std::pair< int64_t, int64_t > &fp_pair, const SQLTypeInfo &ti, const bool float_argument_input)
void addCompilationQueueTime(const int64_t compilation_queue_time)
bool takes_float_argument(const TargetInfo &target_info)
void parallelTop(const std::list< Analyzer::OrderEntry > &order_entries, const size_t top_n, const Executor *executor)
void inplace_sort_gpu(const std::list< Analyzer::OrderEntry > &order_entries, const QueryMemoryDescriptor &query_mem_desc, const GpuGroupByBuffers &group_by_buffers, Data_Namespace::DataMgr *data_mgr, const int device_id)
void apply_permutation_cpu(int64_t *val_buff, int32_t *idx_buff, const uint64_t entry_count, int64_t *tmp_buff, const uint32_t chosen_bytes)
DEVICE void resize(size_type const size)
std::vector< int64_t > materializeCountDistinctColumn(const Analyzer::OrderEntry &order_entry) const
size_t get_truncated_row_count(size_t total_row_count, size_t limit, size_t offset)
size_t parallelRowCount() const
void radixSortOnCpu(const std::list< Analyzer::OrderEntry > &order_entries) const
const SQLTypeInfo get_compact_type(const TargetInfo &target)
bool definitelyHasNoRows() const
bool use_parallel_algorithms(const ResultSet &rows)
bool isZeroCopyColumnarConversionPossible(size_t column_idx) const
size_t g_parallel_top_min
int8_t * getHostEstimatorBuffer() const
DEVICE size_type size() const
const ResultSetStorage * allocateStorage() const
std::shared_ptr< const std::vector< std::string > > getStringDictionaryPayloadCopy(const int dict_id) const
size_t advance_slot(const size_t j, const TargetInfo &target_info, const bool separate_varlen_storage)
int64_t count_distinct_set_size(const int64_t set_handle, const CountDistinctDescriptor &count_distinct_desc)
void sort(const std::list< Analyzer::OrderEntry > &order_entries, size_t top_n, const Executor *executor)
DEVICE auto copy(ARGS &&...args)
void setQueueTime(const int64_t queue_time)
void dropFirstN(const size_t n)
void copy_from_gpu(Data_Namespace::DataMgr *data_mgr, void *dst, const CUdeviceptr src, const size_t num_bytes, const int device_id)
std::vector< PermutationIdx > Permutation
std::tuple< std::vector< bool >, size_t > getSingleSlotTargetBitmap() const
DEVICE auto accumulate(ARGS &&...args)
void * checked_calloc(const size_t nmemb, const size_t size)
StorageLookupResult findStorage(const size_t entry_idx) const
bool is_distinct_target(const TargetInfo &target_info)
std::vector< std::vector< double >> ApproxMedianBuffers
std::function< bool(const PermutationIdx, const PermutationIdx)> Comparator
bool g_enable_smem_group_by true
void radixSortOnGpu(const std::list< Analyzer::OrderEntry > &order_entries) const
const ResultSetStorage * getStorage() const
static double calculateQuantile(quantile::TDigest *const t_digest, double const q)
int64_t getQueueTime() const
SQLTypeInfo getColType(const size_t col_idx) const
ApproxMedianBuffers::value_type materializeApproxMedianColumn(const Analyzer::OrderEntry &order_entry) const
std::tuple< std::vector< bool >, size_t > getSupportedSingleSlotTargetBitmap() const
ExecutorDeviceType getDeviceType() const
const int8_t * getColumnarBuffer(size_t column_idx) const
void copy_group_by_buffers_from_gpu(Data_Namespace::DataMgr *data_mgr, const std::vector< int64_t * > &group_by_buffers, const size_t groups_buffer_size, const CUdeviceptr group_by_dev_buffers_mem, const QueryMemoryDescriptor &query_mem_desc, const unsigned block_size_x, const unsigned grid_size_x, const int device_id, const bool prepend_index_buffer)
void spawn(Function &&f, Args &&...args)
static Data_Namespace::AbstractBuffer * allocGpuAbstractBuffer(Data_Namespace::DataMgr *data_mgr, const size_t num_bytes, const int device_id)
static QueryMemoryDescriptor fixupQueryMemoryDescriptor(const QueryMemoryDescriptor &)
void baselineSort(const std::list< Analyzer::OrderEntry > &order_entries, const size_t top_n, const Executor *executor)
const Permutation & getPermutationBuffer() const
void append(ResultSet &that)
bool didOutputColumnar() const
static PermutationView topPermutation(PermutationView, const size_t n, const Comparator &)
size_t getCurrentRowBufferIndex() const
bool g_enable_watchdog false
#define DEBUG_TIMER(name)
int8_t * getDeviceEstimatorBuffer() const
bool operator()(const PermutationIdx lhs, const PermutationIdx rhs) const
Basic constructors and methods of the row set interface.
const std::vector< int64_t > & getTargetInitVals() const
std::vector< size_t > getSlotIndicesForTargetIndices() const
Allocate GPU memory using GpuBuffers via DataMgr.
bool can_use_parallel_algorithms(const ResultSet &rows)
int64_t getRenderTime() const
void setCachedRowCount(const size_t row_count) const
bool isDirectColumnarConversionPossible() const
size_t binSearchRowCount() const
1.8.5 
