_rel_alg_translator_8cpp_source.html

 /*

  * Copyright 2017 MapD Technologies, Inc.

  *

  * Licensed under the Apache License, Version 2.0 (the "License");

  * you may not use this file except in compliance with the License.

  * You may obtain a copy of the License at

  *

  *     http://www.apache.org/licenses/LICENSE-2.0

  *

  * Unless required by applicable law or agreed to in writing, software

  * distributed under the License is distributed on an "AS IS" BASIS,

  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

  * See the License for the specific language governing permissions and

  * limitations under the License.

  */


 #include "RelAlgTranslator.h"

 #include "Shared/SqlTypesLayout.h"


 #include "CalciteDeserializerUtils.h"

 #include "DateTimePlusRewrite.h"

 #include "DateTimeTranslator.h"

 #include "Descriptors/RelAlgExecutionDescriptor.h"

 #include "ExpressionRewrite.h"

 #include "ExtensionFunctionsBinding.h"

 #include "ExtensionFunctionsWhitelist.h"

 #include "RelAlgAbstractInterpreter.h"

 #include "WindowContext.h"


 #include <future>


 #include "../Analyzer/Analyzer.h"

 #include "../Parser/ParserNode.h"

 #include "../Shared/likely.h"

 #include "../Shared/sql_type_to_string.h"

 #include "../Shared/thread_count.h"


 extern bool g_enable_watchdog;


 bool g_enable_experimental_string_functions = false;


 namespace {


 SQLTypeInfo build_type_info(const SQLTypes sql_type,

                             const int scale,

                             const int precision) {

   SQLTypeInfo ti(sql_type, 0, 0, true);

   ti.set_scale(scale);

   ti.set_precision(precision);

   return ti;

 }


 std::pair<std::shared_ptr<Analyzer::Expr>, SQLQualifier> get_quantified_rhs(

     const RexScalar* rex_scalar,

     const RelAlgTranslator& translator) {

   std::shared_ptr<Analyzer::Expr> rhs;

   SQLQualifier sql_qual{kONE};

   const auto rex_operator = dynamic_cast<const RexOperator*>(rex_scalar);

   if (!rex_operator) {

     return std::make_pair(rhs, sql_qual);

   }

   const auto rex_function = dynamic_cast<const RexFunctionOperator*>(rex_operator);

   const auto qual_str = rex_function ? rex_function->getName() : "";

   if (qual_str == "PG_ANY"sv || qual_str == "PG_ALL"sv) {

     CHECK_EQ(size_t(1), rex_function->size());

     rhs = translator.translateScalarRex(rex_function->getOperand(0));

     sql_qual = (qual_str == "PG_ANY"sv) ? kANY : kALL;

   }

   if (!rhs && rex_operator->getOperator() == kCAST) {

     CHECK_EQ(size_t(1), rex_operator->size());

     std::tie(rhs, sql_qual) = get_quantified_rhs(rex_operator->getOperand(0), translator);

   }

   return std::make_pair(rhs, sql_qual);

 }


 std::pair<Datum, bool> datum_from_scalar_tv(const ScalarTargetValue* scalar_tv,

                                             const SQLTypeInfo& ti) noexcept {

   Datum d{0};

   bool is_null_const{false};

   switch (ti.get_type()) {

     case kTINYINT: {

       const auto ival = boost::get<int64_t>(scalar_tv);

       CHECK(ival);

       if (*ival == inline_int_null_val(ti)) {

         is_null_const = true;

       } else {

         d.tinyintval = *ival;

       }

       break;

     }

     case kSMALLINT: {

       const auto ival = boost::get<int64_t>(scalar_tv);

       CHECK(ival);

       if (*ival == inline_int_null_val(ti)) {

         is_null_const = true;

       } else {

         d.smallintval = *ival;

       }

       break;

     }

     case kINT: {

       const auto ival = boost::get<int64_t>(scalar_tv);

       CHECK(ival);

       if (*ival == inline_int_null_val(ti)) {

         is_null_const = true;

       } else {

         d.intval = *ival;

       }

       break;

     }

     case kDECIMAL:

     case kNUMERIC:

     case kBIGINT:

     case kDATE:

     case kTIME:

     case kTIMESTAMP: {

       const auto ival = boost::get<int64_t>(scalar_tv);

       CHECK(ival);

       if (*ival == inline_int_null_val(ti)) {

         is_null_const = true;

       } else {

         d.bigintval = *ival;

       }

       break;

     }

     case kDOUBLE: {

       const auto dval = boost::get<double>(scalar_tv);

       CHECK(dval);

       if (*dval == inline_fp_null_val(ti)) {

         is_null_const = true;

       } else {

         d.doubleval = *dval;

       }

       break;

     }

     case kFLOAT: {

       const auto fval = boost::get<float>(scalar_tv);

       CHECK(fval);

       if (*fval == inline_fp_null_val(ti)) {

         is_null_const = true;

       } else {

         d.floatval = *fval;

       }

       break;

     }

     case kTEXT:

     case kVARCHAR:

     case kCHAR: {

       auto nullable_sptr = boost::get<NullableString>(scalar_tv);

       CHECK(nullable_sptr);

       if (boost::get<void*>(nullable_sptr)) {

         is_null_const = true;

       } else {

         auto sptr = boost::get<std::string>(nullable_sptr);

         d.stringval = new std::string(*sptr);

       }

       break;

     }

     default:

       CHECK(false);

   }

   return {d, is_null_const};

 }


 }  // namespace


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateScalarRex(

     const RexScalar* rex) const {

   const auto rex_input = dynamic_cast<const RexInput*>(rex);

   if (rex_input) {

     return translateInput(rex_input);

   }

   const auto rex_literal = dynamic_cast<const RexLiteral*>(rex);

   if (rex_literal) {

     return translateLiteral(rex_literal);

   }

   const auto rex_window_function = dynamic_cast<const RexWindowFunctionOperator*>(rex);

   if (rex_window_function) {

     return translateWindowFunction(rex_window_function);

   }

   const auto rex_function = dynamic_cast<const RexFunctionOperator*>(rex);

   if (rex_function) {

     return translateFunction(rex_function);

   }

   const auto rex_operator = dynamic_cast<const RexOperator*>(rex);

   if (rex_operator) {

     return translateOper(rex_operator);

   }

   const auto rex_case = dynamic_cast<const RexCase*>(rex);

   if (rex_case) {

     return translateCase(rex_case);

   }

   const auto rex_subquery = dynamic_cast<const RexSubQuery*>(rex);

   if (rex_subquery) {

     return translateScalarSubquery(rex_subquery);

   }

   CHECK(false);

   return nullptr;

 }


 namespace {


 bool is_agg_supported_for_type(const SQLAgg& agg_kind, const SQLTypeInfo& arg_ti) {

   if ((agg_kind == kMIN || agg_kind == kMAX || agg_kind == kSUM || agg_kind == kAVG) &&

       !(arg_ti.is_number() || arg_ti.is_boolean() || arg_ti.is_time())) {

     return false;

   }


   return true;

 }


 }  // namespace


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateAggregateRex(

     const RexAgg* rex,

     const std::vector<std::shared_ptr<Analyzer::Expr>>& scalar_sources) {

   const auto agg_kind = rex->getKind();

   const bool is_distinct = rex->isDistinct();

   const bool takes_arg{rex->size() > 0};

   std::shared_ptr<Analyzer::Expr> arg_expr;

   std::shared_ptr<Analyzer::Constant> err_rate;

   if (takes_arg) {

     const auto operand = rex->getOperand(0);

     CHECK_LT(operand, scalar_sources.size());

     CHECK_LE(rex->size(), 2u);

     arg_expr = scalar_sources[operand];

     if (agg_kind == kAPPROX_COUNT_DISTINCT && rex->size() == 2) {

       err_rate = std::dynamic_pointer_cast<Analyzer::Constant>(

           scalar_sources[rex->getOperand(1)]);

       if (!err_rate || err_rate->get_type_info().get_type() != kINT ||

           err_rate->get_constval().intval < 1 || err_rate->get_constval().intval > 100) {

         throw std::runtime_error(

             "APPROX_COUNT_DISTINCT's second parameter should be SMALLINT literal between "

             "1 and 100");

       }

     }

     const auto& arg_ti = arg_expr->get_type_info();

     if (!is_agg_supported_for_type(agg_kind, arg_ti)) {

       throw std::runtime_error("Aggregate on " + arg_ti.get_type_name() +

                                " is not supported yet.");

     }

   }

   const auto agg_ti = get_agg_type(agg_kind, arg_expr.get());

   return makeExpr<Analyzer::AggExpr>(agg_ti, agg_kind, arg_expr, is_distinct, err_rate);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateLiteral(

     const RexLiteral* rex_literal) {

   const auto lit_ti = build_type_info(

       rex_literal->getType(), rex_literal->getScale(), rex_literal->getPrecision());

   const auto target_ti = build_type_info(rex_literal->getTargetType(),

                                          rex_literal->getTypeScale(),

                                          rex_literal->getTypePrecision());

   switch (rex_literal->getType()) {

     case kDECIMAL: {

       const auto val = rex_literal->getVal<int64_t>();

       const int precision = rex_literal->getPrecision();

       const int scale = rex_literal->getScale();

       if (target_ti.is_fp() && !scale) {

         return make_fp_constant(val, target_ti);

       }

       auto lit_expr = scale ? Parser::FixedPtLiteral::analyzeValue(val, scale, precision)

                             : Parser::IntLiteral::analyzeValue(val);

       return lit_ti != target_ti ? lit_expr->add_cast(target_ti) : lit_expr;

     }

     case kTEXT: {

       return Parser::StringLiteral::analyzeValue(rex_literal->getVal<std::string>());

     }

     case kBOOLEAN: {

       Datum d;

       d.boolval = rex_literal->getVal<bool>();

       return makeExpr<Analyzer::Constant>(kBOOLEAN, false, d);

     }

     case kDOUBLE: {

       Datum d;

       d.doubleval = rex_literal->getVal<double>();

       auto lit_expr = makeExpr<Analyzer::Constant>(kDOUBLE, false, d);

       return lit_ti != target_ti ? lit_expr->add_cast(target_ti) : lit_expr;

     }

     case kINTERVAL_DAY_TIME:

     case kINTERVAL_YEAR_MONTH: {

       Datum d;

       d.bigintval = rex_literal->getVal<int64_t>();

       return makeExpr<Analyzer::Constant>(rex_literal->getType(), false, d);

     }

     case kTIME:

     case kTIMESTAMP: {

       Datum d;

       d.bigintval =

           rex_literal->getType() == kTIMESTAMP && rex_literal->getPrecision() > 0

               ? rex_literal->getVal<int64_t>()

               : rex_literal->getVal<int64_t>() / 1000;

       return makeExpr<Analyzer::Constant>(

           SQLTypeInfo(rex_literal->getType(), rex_literal->getPrecision(), 0, false),

           false,

           d);

     }

     case kDATE: {

       Datum d;

       d.bigintval = rex_literal->getVal<int64_t>() * 24 * 3600;

       return makeExpr<Analyzer::Constant>(rex_literal->getType(), false, d);

     }

     case kNULLT: {

       return makeExpr<Analyzer::Constant>(rex_literal->getTargetType(), true, Datum{0});

     }

     default: {

       LOG(FATAL) << "Unexpected literal type " << lit_ti.get_type_name();

     }

   }

   return nullptr;

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateScalarSubquery(

     const RexSubQuery* rex_subquery) const {

   if (just_explain_) {

     throw std::runtime_error("EXPLAIN is not supported with sub-queries");

   }

   CHECK(rex_subquery);

   auto result = rex_subquery->getExecutionResult();

   auto row_set = result->getRows();

   if (row_set->rowCount() > size_t(1)) {

     throw std::runtime_error("Scalar sub-query returned multiple rows");

   }

   if (row_set->rowCount() < size_t(1)) {

     CHECK_EQ(row_set->rowCount(), size_t(0));

     throw std::runtime_error("Scalar sub-query returned no results");

   }

   auto first_row = row_set->getNextRow(false, false);

   auto scalar_tv = boost::get<ScalarTargetValue>(&first_row[0]);

   auto ti = rex_subquery->getType();

   if (ti.is_string()) {

     throw std::runtime_error("Scalar sub-queries which return strings not supported");

   }

   Datum d{0};

   bool is_null_const{false};

   std::tie(d, is_null_const) = datum_from_scalar_tv(scalar_tv, ti);

   return makeExpr<Analyzer::Constant>(ti, is_null_const, d);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateInput(

     const RexInput* rex_input) const {

   const auto source = rex_input->getSourceNode();

   const auto it_rte_idx = input_to_nest_level_.find(source);

   CHECK(it_rte_idx != input_to_nest_level_.end());

   const int rte_idx = it_rte_idx->second;

   const auto scan_source = dynamic_cast<const RelScan*>(source);

   const auto& in_metainfo = source->getOutputMetainfo();

   if (scan_source) {

     // We're at leaf (scan) level and not supposed to have input metadata,

     // the name and type information come directly from the catalog.

     CHECK(in_metainfo.empty());

     const auto table_desc = scan_source->getTableDescriptor();

     const auto cd =

         cat_.getMetadataForColumnBySpi(table_desc->tableId, rex_input->getIndex() + 1);

     CHECK(cd);

     auto col_ti = cd->columnType;

     if (col_ti.is_string()) {

       col_ti.set_type(kTEXT);

     }

     if (cd->isVirtualCol) {

       // TODO(alex): remove at some point, we only need this fixup for backwards

       // compatibility with old imported data

       CHECK_EQ("rowid", cd->columnName);

       col_ti.set_size(8);

     }

     CHECK_LE(static_cast<size_t>(rte_idx), join_types_.size());

     if (rte_idx > 0 && join_types_[rte_idx - 1] == JoinType::LEFT) {

       col_ti.set_notnull(false);

     }

     return std::make_shared<Analyzer::ColumnVar>(

         col_ti, table_desc->tableId, cd->columnId, rte_idx);

   }

   CHECK(!in_metainfo.empty());

   CHECK_GE(rte_idx, 0);

   const size_t col_id = rex_input->getIndex();

   CHECK_LT(col_id, in_metainfo.size());

   auto col_ti = in_metainfo[col_id].get_type_info();

   CHECK_LE(static_cast<size_t>(rte_idx), join_types_.size());

   if (rte_idx > 0 && join_types_[rte_idx - 1] == JoinType::LEFT) {

     col_ti.set_notnull(false);

   }

   return std::make_shared<Analyzer::ColumnVar>(col_ti, -source->getId(), col_id, rte_idx);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateUoper(

     const RexOperator* rex_operator) const {

   CHECK_EQ(size_t(1), rex_operator->size());

   const auto operand_expr = translateScalarRex(rex_operator->getOperand(0));

   const auto sql_op = rex_operator->getOperator();

   switch (sql_op) {

     case kCAST: {

       const auto& target_ti = rex_operator->getType();

       CHECK_NE(kNULLT, target_ti.get_type());

       const auto& operand_ti = operand_expr->get_type_info();

       if (operand_ti.is_string() && target_ti.is_string()) {

         return operand_expr;

       }

       if (target_ti.is_time() ||

           operand_ti

               .is_string()) {  // TODO(alex): check and unify with the rest of the cases

         // Do not propogate encoding on small dates

         return target_ti.is_date_in_days()

                    ? operand_expr->add_cast(SQLTypeInfo(kDATE, false))

                    : operand_expr->add_cast(target_ti);

       }

       if (!operand_ti.is_string() && target_ti.is_string()) {

         return operand_expr->add_cast(target_ti);

       }


       return std::make_shared<Analyzer::UOper>(target_ti, false, sql_op, operand_expr);

     }

     case kNOT:

     case kISNULL: {

       return std::make_shared<Analyzer::UOper>(kBOOLEAN, sql_op, operand_expr);

     }

     case kISNOTNULL: {

       auto is_null = std::make_shared<Analyzer::UOper>(kBOOLEAN, kISNULL, operand_expr);

       return std::make_shared<Analyzer::UOper>(kBOOLEAN, kNOT, is_null);

     }

     case kMINUS: {

       const auto& ti = operand_expr->get_type_info();

       return std::make_shared<Analyzer::UOper>(ti, false, kUMINUS, operand_expr);

     }

     case kUNNEST: {

       const auto& ti = operand_expr->get_type_info();

       CHECK(ti.is_array());

       return makeExpr<Analyzer::UOper>(ti.get_elem_type(), false, kUNNEST, operand_expr);

     }

     default:

       CHECK(false);

   }

   return nullptr;

 }


 namespace {


 std::shared_ptr<Analyzer::Expr> get_in_values_expr(std::shared_ptr<Analyzer::Expr> arg,

                                                    const ResultSet& val_set) {

   if (!can_use_parallel_algorithms(val_set)) {

     return nullptr;

   }

   if (val_set.rowCount() > 5000000 && g_enable_watchdog) {

     throw std::runtime_error(

         "Unable to handle 'expr IN (subquery)', subquery returned 5M+ rows.");

   }

   std::list<std::shared_ptr<Analyzer::Expr>> value_exprs;

   const size_t fetcher_count = cpu_threads();

   std::vector<std::list<std::shared_ptr<Analyzer::Expr>>> expr_set(

       fetcher_count, std::list<std::shared_ptr<Analyzer::Expr>>());

   std::vector<std::future<void>> fetcher_threads;

   const auto& ti = arg->get_type_info();

   const auto entry_count = val_set.entryCount();

   for (size_t i = 0,

               start_entry = 0,

               stride = (entry_count + fetcher_count - 1) / fetcher_count;

        i < fetcher_count && start_entry < entry_count;

        ++i, start_entry += stride) {

     const auto end_entry = std::min(start_entry + stride, entry_count);

     fetcher_threads.push_back(std::async(

         std::launch::async,

         [&](std::list<std::shared_ptr<Analyzer::Expr>>& in_vals,

             const size_t start,

             const size_t end) {

           for (auto index = start; index < end; ++index) {

             auto row = val_set.getRowAt(index);

             if (row.empty()) {

               continue;

             }

             auto scalar_tv = boost::get<ScalarTargetValue>(&row[0]);

             Datum d{0};

             bool is_null_const{false};

             std::tie(d, is_null_const) = datum_from_scalar_tv(scalar_tv, ti);

             if (ti.is_string() && ti.get_compression() != kENCODING_NONE) {

               auto ti_none_encoded = ti;

               ti_none_encoded.set_compression(kENCODING_NONE);

               auto none_encoded_string =

                   makeExpr<Analyzer::Constant>(ti, is_null_const, d);

               auto dict_encoded_string = std::make_shared<Analyzer::UOper>(

                   ti, false, kCAST, none_encoded_string);

               in_vals.push_back(dict_encoded_string);

             } else {

               in_vals.push_back(makeExpr<Analyzer::Constant>(ti, is_null_const, d));

             }

           }

         },

         std::ref(expr_set[i]),

         start_entry,

         end_entry));

   }

   for (auto& child : fetcher_threads) {

     child.get();

   }


   val_set.moveToBegin();

   for (auto& exprs : expr_set) {

     value_exprs.splice(value_exprs.end(), exprs);

   }

   return makeExpr<Analyzer::InValues>(arg, value_exprs);

 }


 }  // namespace


 // Creates an Analyzer expression for an IN subquery which subsequently goes through the

 // regular Executor::codegen() mechanism. The creation of the expression out of subquery's

 // result set is parallelized whenever possible. In addition, take advantage of additional

 // information that elements in the right hand side are constants; see

 // getInIntegerSetExpr().

 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateInOper(

     const RexOperator* rex_operator) const {

   if (just_explain_) {

     throw std::runtime_error("EXPLAIN is not supported with sub-queries");

   }

   CHECK(rex_operator->size() == 2);

   const auto lhs = translateScalarRex(rex_operator->getOperand(0));

   const auto rhs = rex_operator->getOperand(1);

   const auto rex_subquery = dynamic_cast<const RexSubQuery*>(rhs);

   CHECK(rex_subquery);

   auto ti = lhs->get_type_info();

   auto result = rex_subquery->getExecutionResult();

   auto& row_set = result->getRows();

   CHECK_EQ(size_t(1), row_set->colCount());

   const auto& rhs_ti = row_set->getColType(0);

   if (rhs_ti.get_type() != ti.get_type()) {

     throw std::runtime_error(

         "The two sides of the IN operator must have the same type; found " +

         ti.get_type_name() + " and " + rhs_ti.get_type_name());

   }

   row_set->moveToBegin();

   if (row_set->entryCount() > 10000) {

     std::shared_ptr<Analyzer::Expr> expr;

     if ((ti.is_integer() || (ti.is_string() && ti.get_compression() == kENCODING_DICT)) &&

         !row_set->getQueryMemDesc().didOutputColumnar()) {

       expr = getInIntegerSetExpr(lhs, *row_set);

       // Handle the highly unlikely case when the InIntegerSet ended up being tiny.

       // Just let it fall through the usual InValues path at the end of this method,

       // its codegen knows to use inline comparisons for few values.

       if (expr && std::static_pointer_cast<Analyzer::InIntegerSet>(expr)

                           ->get_value_list()

                           .size() <= 100) {

         expr = nullptr;

       }

     } else {

       expr = get_in_values_expr(lhs, *row_set);

     }

     if (expr) {

       return expr;

     }

   }

   std::list<std::shared_ptr<Analyzer::Expr>> value_exprs;

   while (true) {

     auto row = row_set->getNextRow(true, false);

     if (row.empty()) {

       break;

     }

     if (g_enable_watchdog && value_exprs.size() >= 10000) {

       throw std::runtime_error(

           "Unable to handle 'expr IN (subquery)', subquery returned 10000+ rows.");

     }

     auto scalar_tv = boost::get<ScalarTargetValue>(&row[0]);

     Datum d{0};

     bool is_null_const{false};

     std::tie(d, is_null_const) = datum_from_scalar_tv(scalar_tv, ti);

     if (ti.is_string() && ti.get_compression() != kENCODING_NONE) {

       auto ti_none_encoded = ti;

       ti_none_encoded.set_compression(kENCODING_NONE);

       auto none_encoded_string = makeExpr<Analyzer::Constant>(ti, is_null_const, d);

       auto dict_encoded_string =

           std::make_shared<Analyzer::UOper>(ti, false, kCAST, none_encoded_string);

       value_exprs.push_back(dict_encoded_string);

     } else {

       value_exprs.push_back(makeExpr<Analyzer::Constant>(ti, is_null_const, d));

     }

   }

   return makeExpr<Analyzer::InValues>(lhs, value_exprs);

 }


 namespace {


 const size_t g_max_integer_set_size{1 << 25};


 void fill_dictionary_encoded_in_vals(

     std::vector<int64_t>& in_vals,

     std::atomic<size_t>& total_in_vals_count,

     const ResultSet* values_rowset,

     const std::pair<int64_t, int64_t> values_rowset_slice,

     const StringDictionaryProxy* source_dict,

     const StringDictionaryProxy* dest_dict,

     const int64_t needle_null_val) {

   CHECK(in_vals.empty());

   bool dicts_are_equal = source_dict == dest_dict;

   for (auto index = values_rowset_slice.first; index < values_rowset_slice.second;

        ++index) {

     const auto row = values_rowset->getOneColRow(index);

     if (UNLIKELY(!row.valid)) {

       continue;

     }

     if (dicts_are_equal) {

       in_vals.push_back(row.value);

     } else {

       const int string_id =

           row.value == needle_null_val

               ? needle_null_val

               : dest_dict->getIdOfString(source_dict->getString(row.value));

       if (string_id != StringDictionary::INVALID_STR_ID) {

         in_vals.push_back(string_id);

       }

     }

     if (UNLIKELY(g_enable_watchdog && (in_vals.size() & 1023) == 0 &&

                  total_in_vals_count.fetch_add(1024) >= g_max_integer_set_size)) {

       throw std::runtime_error(

           "Unable to handle 'expr IN (subquery)', subquery returned 30M+ rows.");

     }

   }

 }


 void fill_integer_in_vals(std::vector<int64_t>& in_vals,

                           std::atomic<size_t>& total_in_vals_count,

                           const ResultSet* values_rowset,

                           const std::pair<int64_t, int64_t> values_rowset_slice) {

   CHECK(in_vals.empty());

   for (auto index = values_rowset_slice.first; index < values_rowset_slice.second;

        ++index) {

     const auto row = values_rowset->getOneColRow(index);

     if (row.valid) {

       in_vals.push_back(row.value);

       if (UNLIKELY(g_enable_watchdog && (in_vals.size() & 1023) == 0 &&

                    total_in_vals_count.fetch_add(1024) >= g_max_integer_set_size)) {

         throw std::runtime_error(

             "Unable to handle 'expr IN (subquery)', subquery returned 30M+ rows.");

       }

     }

   }

 }


 // Multi-node counterpart of the other version. Saves round-trips, which is crucial

 // for a big right-hand side result. It only handles physical string dictionary ids,

 // therefore it won't be able to handle a right-hand side sub-query with a CASE

 // returning literals on some branches. That case isn't hard too handle either, but

 // it's not clear it's actually important in practice.

 // RelAlgTranslator::getInIntegerSetExpr makes sure, by checking the encodings, that this

 // function isn't called in such cases.

 void fill_dictionary_encoded_in_vals(

     std::vector<int64_t>& in_vals,

     std::atomic<size_t>& total_in_vals_count,

     const ResultSet* values_rowset,

     const std::pair<int64_t, int64_t> values_rowset_slice,

     const std::vector<LeafHostInfo>& leaf_hosts,

     const DictRef source_dict_ref,

     const DictRef dest_dict_ref,

     const int32_t dest_generation,

     const int64_t needle_null_val) {

   CHECK(in_vals.empty());

   std::vector<int32_t> source_ids;

   source_ids.reserve(values_rowset->entryCount());

   bool has_nulls = false;

   if (source_dict_ref == dest_dict_ref) {

     in_vals.reserve(values_rowset_slice.second - values_rowset_slice.first +

                     1);  // Add 1 to cover interval

     for (auto index = values_rowset_slice.first; index < values_rowset_slice.second;

          ++index) {

       const auto row = values_rowset->getOneColRow(index);

       if (!row.valid) {

         continue;

       }

       if (row.value != needle_null_val) {

         in_vals.push_back(row.value);

         if (UNLIKELY(g_enable_watchdog && (in_vals.size() & 1023) == 0 &&

                      total_in_vals_count.fetch_add(1024) >= g_max_integer_set_size)) {

           throw std::runtime_error(

               "Unable to handle 'expr IN (subquery)', subquery returned 30M+ rows.");

         }

       } else {

         has_nulls = true;

       }

     }

     if (has_nulls) {

       in_vals.push_back(

           needle_null_val);  // we've deduped null values as an optimization, although

                              // this is not required by consumer

     }

     return;

   }

   // Code path below is for when dictionaries are not shared

   for (auto index = values_rowset_slice.first; index < values_rowset_slice.second;

        ++index) {

     const auto row = values_rowset->getOneColRow(index);

     if (row.valid) {

       if (row.value != needle_null_val) {

         source_ids.push_back(row.value);

       } else {

         has_nulls = true;

       }

     }

   }

   std::vector<int32_t> dest_ids;

   translate_string_ids(dest_ids,

                        leaf_hosts.front(),

                        dest_dict_ref,

                        source_ids,

                        source_dict_ref,

                        dest_generation);

   CHECK_EQ(dest_ids.size(), source_ids.size());

   in_vals.reserve(dest_ids.size() + (has_nulls ? 1 : 0));

   if (has_nulls) {

     in_vals.push_back(needle_null_val);

   }

   for (const int32_t dest_id : dest_ids) {

     if (dest_id != StringDictionary::INVALID_STR_ID) {

       in_vals.push_back(dest_id);

       if (UNLIKELY(g_enable_watchdog && (in_vals.size() & 1023) == 0 &&

                    total_in_vals_count.fetch_add(1024) >= g_max_integer_set_size)) {

         throw std::runtime_error(

             "Unable to handle 'expr IN (subquery)', subquery returned 30M+ rows.");

       }

     }

   }

 }


 }  // namespace


 // The typical IN subquery involves either dictionary-encoded strings or integers.

 // Analyzer::InValues is a very heavy representation of the right hand side of such

 // a query since we already know the right hand would be a list of Analyzer::Constant

 // shared pointers. We can avoid the big overhead of each Analyzer::Constant and the

 // refcounting associated with shared pointers by creating an abbreviated InIntegerSet

 // representation of the IN expression which takes advantage of the this information.

 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::getInIntegerSetExpr(

     std::shared_ptr<Analyzer::Expr> arg,

     const ResultSet& val_set) const {

   if (!can_use_parallel_algorithms(val_set)) {

     return nullptr;

   }

   std::vector<int64_t> value_exprs;

   const size_t fetcher_count = cpu_threads();

   std::vector<std::vector<int64_t>> expr_set(fetcher_count);

   std::vector<std::future<void>> fetcher_threads;

   const auto& arg_type = arg->get_type_info();

   const auto entry_count = val_set.entryCount();

   CHECK_EQ(size_t(1), val_set.colCount());

   const auto& col_type = val_set.getColType(0);

   if (g_cluster && arg_type.is_string() &&

       (col_type.get_comp_param() <= 0 || arg_type.get_comp_param() <= 0)) {

     // Skip this case for now, see comment for fill_dictionary_encoded_in_vals.

     return nullptr;

   }

   std::atomic<size_t> total_in_vals_count{0};

   for (size_t i = 0,

               start_entry = 0,

               stride = (entry_count + fetcher_count - 1) / fetcher_count;

        i < fetcher_count && start_entry < entry_count;

        ++i, start_entry += stride) {

     expr_set[i].reserve(entry_count / fetcher_count);

     const auto end_entry = std::min(start_entry + stride, entry_count);

     if (arg_type.is_string()) {

       CHECK_EQ(kENCODING_DICT, arg_type.get_compression());

       // const int32_t dest_dict_id = arg_type.get_comp_param();

       // const int32_t source_dict_id = col_type.get_comp_param();

       const DictRef dest_dict_ref(arg_type.get_comp_param(), cat_.getDatabaseId());

       const DictRef source_dict_ref(col_type.get_comp_param(), cat_.getDatabaseId());

       const auto dd = executor_->getStringDictionaryProxy(

           arg_type.get_comp_param(), val_set.getRowSetMemOwner(), true);

       const auto sd = executor_->getStringDictionaryProxy(

           col_type.get_comp_param(), val_set.getRowSetMemOwner(), true);

       CHECK(sd);

       const auto needle_null_val = inline_int_null_val(arg_type);

       fetcher_threads.push_back(std::async(

           std::launch::async,

           [this,

            &val_set,

            &total_in_vals_count,

            sd,

            dd,

            source_dict_ref,

            dest_dict_ref,

            needle_null_val](

               std::vector<int64_t>& in_vals, const size_t start, const size_t end) {

             if (g_cluster) {

               CHECK_GE(dd->getGeneration(), 0);

               fill_dictionary_encoded_in_vals(in_vals,

                                               total_in_vals_count,

                                               &val_set,

                                               {start, end},

                                               cat_.getStringDictionaryHosts(),

                                               source_dict_ref,

                                               dest_dict_ref,

                                               dd->getGeneration(),

                                               needle_null_val);

             } else {

               fill_dictionary_encoded_in_vals(in_vals,

                                               total_in_vals_count,

                                               &val_set,

                                               {start, end},

                                               sd,

                                               dd,

                                               needle_null_val);

             }

           },

           std::ref(expr_set[i]),

           start_entry,

           end_entry));

     } else {

       CHECK(arg_type.is_integer());

       fetcher_threads.push_back(std::async(

           std::launch::async,

           [&val_set, &total_in_vals_count](

               std::vector<int64_t>& in_vals, const size_t start, const size_t end) {

             fill_integer_in_vals(in_vals, total_in_vals_count, &val_set, {start, end});

           },

           std::ref(expr_set[i]),

           start_entry,

           end_entry));

     }

   }

   for (auto& child : fetcher_threads) {

     child.get();

   }


   val_set.moveToBegin();

   value_exprs.reserve(entry_count);

   for (auto& exprs : expr_set) {

     value_exprs.insert(value_exprs.end(), exprs.begin(), exprs.end());

   }

   return makeExpr<Analyzer::InIntegerSet>(

       arg, value_exprs, arg_type.get_notnull() && col_type.get_notnull());

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateOper(

     const RexOperator* rex_operator) const {

   CHECK_GT(rex_operator->size(), size_t(0));

   if (rex_operator->size() == 1) {

     return translateUoper(rex_operator);

   }

   const auto sql_op = rex_operator->getOperator();

   if (sql_op == kIN) {

     return translateInOper(rex_operator);

   }

   if (sql_op == kMINUS || sql_op == kPLUS) {

     auto date_plus_minus = translateDatePlusMinus(rex_operator);

     if (date_plus_minus) {

       return date_plus_minus;

     }

   }

   if (sql_op == kOVERLAPS) {

     return translateOverlapsOper(rex_operator);

   } else if (IS_COMPARISON(sql_op)) {

     auto geo_comp = translateGeoComparison(rex_operator);

     if (geo_comp) {

       return geo_comp;

     }

   }

   auto lhs = translateScalarRex(rex_operator->getOperand(0));

   for (size_t i = 1; i < rex_operator->size(); ++i) {

     std::shared_ptr<Analyzer::Expr> rhs;

     SQLQualifier sql_qual{kONE};

     const auto rhs_op = rex_operator->getOperand(i);

     std::tie(rhs, sql_qual) = get_quantified_rhs(rhs_op, *this);

     if (!rhs) {

       rhs = translateScalarRex(rhs_op);

     }

     CHECK(rhs);

     lhs = Parser::OperExpr::normalize(sql_op, sql_qual, lhs, rhs);

   }

   return lhs;

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateOverlapsOper(

     const RexOperator* rex_operator) const {

   const auto sql_op = rex_operator->getOperator();

   CHECK(sql_op == kOVERLAPS);


   const auto lhs = translateScalarRex(rex_operator->getOperand(0));

   const auto lhs_ti = lhs->get_type_info();

   if (lhs_ti.is_geometry()) {

     return translateGeoOverlapsOper(rex_operator);

   } else {

     throw std::runtime_error(

         "Overlaps equivalence is currently only supported for geospatial types");

   }

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateCase(

     const RexCase* rex_case) const {

   std::shared_ptr<Analyzer::Expr> else_expr;

   std::list<std::pair<std::shared_ptr<Analyzer::Expr>, std::shared_ptr<Analyzer::Expr>>>

       expr_list;

   for (size_t i = 0; i < rex_case->branchCount(); ++i) {

     const auto when_expr = translateScalarRex(rex_case->getWhen(i));

     const auto then_expr = translateScalarRex(rex_case->getThen(i));

     expr_list.emplace_back(when_expr, then_expr);

   }

   if (rex_case->getElse()) {

     else_expr = translateScalarRex(rex_case->getElse());

   }

   return Parser::CaseExpr::normalize(expr_list, else_expr);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateLike(

     const RexFunctionOperator* rex_function) const {

   CHECK(rex_function->size() == 2 || rex_function->size() == 3);

   const auto arg = translateScalarRex(rex_function->getOperand(0));

   const auto like = translateScalarRex(rex_function->getOperand(1));

   if (!std::dynamic_pointer_cast<const Analyzer::Constant>(like)) {

     throw std::runtime_error("The matching pattern must be a literal.");

   }

   const auto escape = (rex_function->size() == 3)

                           ? translateScalarRex(rex_function->getOperand(2))

                           : nullptr;

   const bool is_ilike = rex_function->getName() == "PG_ILIKE"sv;

   return Parser::LikeExpr::get(arg, like, escape, is_ilike, false);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateRegexp(

     const RexFunctionOperator* rex_function) const {

   CHECK(rex_function->size() == 2 || rex_function->size() == 3);

   const auto arg = translateScalarRex(rex_function->getOperand(0));

   const auto pattern = translateScalarRex(rex_function->getOperand(1));

   if (!std::dynamic_pointer_cast<const Analyzer::Constant>(pattern)) {

     throw std::runtime_error("The matching pattern must be a literal.");

   }

   const auto escape = (rex_function->size() == 3)

                           ? translateScalarRex(rex_function->getOperand(2))

                           : nullptr;

   return Parser::RegexpExpr::get(arg, pattern, escape, false);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateLikely(

     const RexFunctionOperator* rex_function) const {

   CHECK(rex_function->size() == 1);

   const auto arg = translateScalarRex(rex_function->getOperand(0));

   return makeExpr<Analyzer::LikelihoodExpr>(arg, 0.9375);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateUnlikely(

     const RexFunctionOperator* rex_function) const {

   CHECK(rex_function->size() == 1);

   const auto arg = translateScalarRex(rex_function->getOperand(0));

   return makeExpr<Analyzer::LikelihoodExpr>(arg, 0.0625);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateExtract(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(2), rex_function->size());

   const auto timeunit = translateScalarRex(rex_function->getOperand(0));

   const auto timeunit_lit = std::dynamic_pointer_cast<Analyzer::Constant>(timeunit);

   if (!timeunit_lit) {

     throw std::runtime_error("The time unit parameter must be a literal.");

   }

   const auto from_expr = translateScalarRex(rex_function->getOperand(1));

   const bool is_date_trunc = rex_function->getName() == "PG_DATE_TRUNC"sv;

   if (is_date_trunc) {

     return DateTruncExpr::generate(from_expr, *timeunit_lit->get_constval().stringval);

   } else {

     return ExtractExpr::generate(from_expr, *timeunit_lit->get_constval().stringval);

   }

 }


 namespace {


 std::shared_ptr<Analyzer::Constant> makeNumericConstant(const SQLTypeInfo& ti,

                                                         const long val) {

   CHECK(ti.is_number());

   Datum datum{0};

   switch (ti.get_type()) {

     case kTINYINT: {

       datum.tinyintval = val;

       break;

     }

     case kSMALLINT: {

       datum.smallintval = val;

       break;

     }

     case kINT: {

       datum.intval = val;

       break;

     }

     case kBIGINT: {

       datum.bigintval = val;

       break;

     }

     case kDECIMAL:

     case kNUMERIC: {

       datum.bigintval = val * exp_to_scale(ti.get_scale());

       break;

     }

     case kFLOAT: {

       datum.floatval = val;

       break;

     }

     case kDOUBLE: {

       datum.doubleval = val;

       break;

     }

     default:

       CHECK(false);

   }

   return makeExpr<Analyzer::Constant>(ti, false, datum);

 }


 }  // namespace


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateDateadd(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(3), rex_function->size());

   const auto timeunit = translateScalarRex(rex_function->getOperand(0));

   const auto timeunit_lit = std::dynamic_pointer_cast<Analyzer::Constant>(timeunit);

   if (!timeunit_lit) {

     throw std::runtime_error("The time unit parameter must be a literal.");

   }


   const auto number_units = translateScalarRex(rex_function->getOperand(1));

   auto cast_number_units = number_units->add_cast(SQLTypeInfo(kBIGINT, false));

   const auto datetime = translateScalarRex(rex_function->getOperand(2));

   const auto& datetime_ti = datetime->get_type_info();

   if (datetime_ti.get_type() == kTIME) {

     throw std::runtime_error("DateAdd operation not supported for TIME.");

   }

   const auto& field = to_dateadd_field(*timeunit_lit->get_constval().stringval);

   if (!datetime_ti.is_high_precision_timestamp() &&

       DateTimeUtils::is_subsecond_dateadd_field(field)) {

     // Scale the number to get value in seconds

     const auto bigint_ti = SQLTypeInfo(kBIGINT, false);

     cast_number_units = makeExpr<Analyzer::BinOper>(

         bigint_ti.get_type(),

         kDIVIDE,

         kONE,

         cast_number_units,

         makeNumericConstant(bigint_ti,

                             DateTimeUtils::get_dateadd_timestamp_precision_scale(field)));

     cast_number_units = fold_expr(cast_number_units.get());

   }

   if (datetime_ti.is_high_precision_timestamp() &&

       DateTimeUtils::is_subsecond_dateadd_field(field)) {

     const auto oper_scale = DateTimeUtils::get_dateadd_high_precision_adjusted_scale(

         field, datetime_ti.get_dimension());

     if (oper_scale.first) {

       // scale number to desired precision

       const auto bigint_ti = SQLTypeInfo(kBIGINT, false);

       cast_number_units =

           makeExpr<Analyzer::BinOper>(bigint_ti.get_type(),

                                       oper_scale.first,

                                       kONE,

                                       cast_number_units,

                                       makeNumericConstant(bigint_ti, oper_scale.second));

       cast_number_units = fold_expr(cast_number_units.get());

     }

   }

   return makeExpr<Analyzer::DateaddExpr>(

       SQLTypeInfo(kTIMESTAMP, datetime_ti.get_dimension(), 0, false),

       to_dateadd_field(*timeunit_lit->get_constval().stringval),

       cast_number_units,

       datetime);

 }


 namespace {


 std::string get_datetimeplus_rewrite_funcname(const SQLOps& op) {

   CHECK(op == kPLUS);

   return "DATETIME_PLUS"s;

 }


 }  // namespace


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateDatePlusMinus(

     const RexOperator* rex_operator) const {

   if (rex_operator->size() != 2) {

     return nullptr;

   }

   const auto datetime = translateScalarRex(rex_operator->getOperand(0));

   const auto datetime_ti = datetime->get_type_info();

   if (!datetime_ti.is_timestamp() && !datetime_ti.is_date()) {

     if (datetime_ti.get_type() == kTIME) {

       throw std::runtime_error("DateTime addition/subtraction not supported for TIME.");

     }

     return nullptr;

   }

   const auto rhs = translateScalarRex(rex_operator->getOperand(1));

   const auto rhs_ti = rhs->get_type_info();

   if (rhs_ti.get_type() == kTIMESTAMP || rhs_ti.get_type() == kDATE) {

     if (datetime_ti.is_high_precision_timestamp() ||

         rhs_ti.is_high_precision_timestamp()) {

       throw std::runtime_error(

           "High Precision timestamps are not supported for TIMESTAMPDIFF operation. Use "

           "DATEDIFF.");

     }

     auto bigint_ti = SQLTypeInfo(kBIGINT, false);

     const auto& rex_operator_ti = rex_operator->getType();

     const auto datediff_field =

         (rex_operator_ti.get_type() == kINTERVAL_DAY_TIME) ? dtSECOND : dtMONTH;

     auto result =

         makeExpr<Analyzer::DatediffExpr>(bigint_ti, datediff_field, rhs, datetime);

     // multiply 1000 to result since expected result should be in millisecond precision.

     if (rex_operator_ti.get_type() == kINTERVAL_DAY_TIME) {

       return makeExpr<Analyzer::BinOper>(bigint_ti.get_type(),

                                          kMULTIPLY,

                                          kONE,

                                          result,

                                          makeNumericConstant(bigint_ti, 1000));

     } else {

       return result;

     }

   }

   const auto op = rex_operator->getOperator();

   if (op == kPLUS) {

     std::vector<std::shared_ptr<Analyzer::Expr>> args = {datetime, rhs};

     auto dt_plus = makeExpr<Analyzer::FunctionOper>(

         datetime_ti, get_datetimeplus_rewrite_funcname(op), args);

     const auto date_trunc = rewrite_to_date_trunc(dt_plus.get());

     if (date_trunc) {

       return date_trunc;

     }

   }

   const auto interval = fold_expr(rhs.get());

   auto interval_ti = interval->get_type_info();

   auto bigint_ti = SQLTypeInfo(kBIGINT, false);

   const auto interval_lit = std::dynamic_pointer_cast<Analyzer::Constant>(interval);

   if (interval_ti.get_type() == kINTERVAL_DAY_TIME) {

     std::shared_ptr<Analyzer::Expr> interval_sec;

     if (interval_lit) {

       interval_sec =

           makeNumericConstant(bigint_ti,

                               (op == kMINUS ? -interval_lit->get_constval().bigintval

                                             : interval_lit->get_constval().bigintval) /

                                   1000);

     } else {

       interval_sec = makeExpr<Analyzer::BinOper>(bigint_ti.get_type(),

                                                  kDIVIDE,

                                                  kONE,

                                                  interval,

                                                  makeNumericConstant(bigint_ti, 1000));

       if (op == kMINUS) {

         interval_sec =

             std::make_shared<Analyzer::UOper>(bigint_ti, false, kUMINUS, interval_sec);

       }

     }

     return makeExpr<Analyzer::DateaddExpr>(datetime_ti, daSECOND, interval_sec, datetime);

   }

   CHECK(interval_ti.get_type() == kINTERVAL_YEAR_MONTH);

   const auto interval_months = op == kMINUS ? std::make_shared<Analyzer::UOper>(

                                                   bigint_ti, false, kUMINUS, interval)

                                             : interval;

   return makeExpr<Analyzer::DateaddExpr>(datetime_ti, daMONTH, interval_months, datetime);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateDatediff(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(3), rex_function->size());

   const auto timeunit = translateScalarRex(rex_function->getOperand(0));

   const auto timeunit_lit = std::dynamic_pointer_cast<Analyzer::Constant>(timeunit);

   if (!timeunit_lit) {

     throw std::runtime_error("The time unit parameter must be a literal.");

   }

   const auto start = translateScalarRex(rex_function->getOperand(1));

   const auto end = translateScalarRex(rex_function->getOperand(2));

   const auto field = to_datediff_field(*timeunit_lit->get_constval().stringval);

   return makeExpr<Analyzer::DatediffExpr>(SQLTypeInfo(kBIGINT, false), field, start, end);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateDatepart(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(2), rex_function->size());

   const auto timeunit = translateScalarRex(rex_function->getOperand(0));

   const auto timeunit_lit = std::dynamic_pointer_cast<Analyzer::Constant>(timeunit);

   if (!timeunit_lit) {

     throw std::runtime_error("The time unit parameter must be a literal.");

   }

   const auto from_expr = translateScalarRex(rex_function->getOperand(1));

   return ExtractExpr::generate(

       from_expr, to_datepart_field(*timeunit_lit->get_constval().stringval));

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateLength(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(1), rex_function->size());

   const auto str_arg = translateScalarRex(rex_function->getOperand(0));

   return makeExpr<Analyzer::CharLengthExpr>(str_arg->decompress(),

                                             rex_function->getName() == "CHAR_LENGTH"sv);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateKeyForString(

     const RexFunctionOperator* rex_function) const {

   const auto& args = translateFunctionArgs(rex_function);

   CHECK_EQ(size_t(1), args.size());

   const auto expr = dynamic_cast<Analyzer::Expr*>(args[0].get());

   if (nullptr == expr || !expr->get_type_info().is_string() ||

       expr->get_type_info().is_varlen()) {

     throw std::runtime_error(rex_function->getName() +

                              " expects a dictionary encoded text column.");

   }

   return makeExpr<Analyzer::KeyForStringExpr>(args[0]);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateLower(

     const RexFunctionOperator* rex_function) const {

   const auto& args = translateFunctionArgs(rex_function);

   CHECK_EQ(size_t(1), args.size());

   CHECK(args[0]);


   if (args[0]->get_type_info().is_dict_encoded_string() ||

       dynamic_cast<Analyzer::Constant*>(args[0].get())) {

     return makeExpr<Analyzer::LowerExpr>(args[0]);

   }


   throw std::runtime_error(rex_function->getName() +

                            " expects a dictionary encoded text column or a literal.");

 }


 Analyzer::ExpressionPtr RelAlgTranslator::translateCardinality(

     const RexFunctionOperator* rex_function) const {

   const auto ret_ti = rex_function->getType();

   const auto arg = translateScalarRex(rex_function->getOperand(0));

   const auto arg_ti = arg->get_type_info();

   if (!arg_ti.is_array()) {

     throw std::runtime_error(rex_function->getName() + " expects an array expression.");

   }

   if (arg_ti.get_subtype() == kARRAY) {

     throw std::runtime_error(rex_function->getName() +

                              " expects one-dimension array expression.");

   }

   const auto array_size = arg_ti.get_size();

   const auto array_elem_size = arg_ti.get_elem_type().get_array_context_logical_size();


   if (array_size > 0) {

     if (array_elem_size <= 0) {

       throw std::runtime_error(rex_function->getName() +

                                ": unexpected array element type.");

     }

     // Return cardinality of a fixed length array

     return makeNumericConstant(ret_ti, array_size / array_elem_size);

   }

   // Variable length array cardinality will be calculated at runtime

   return makeExpr<Analyzer::CardinalityExpr>(arg);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateItem(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(2), rex_function->size());

   const auto base = translateScalarRex(rex_function->getOperand(0));

   const auto index = translateScalarRex(rex_function->getOperand(1));

   return makeExpr<Analyzer::BinOper>(

       base->get_type_info().get_elem_type(), false, kARRAY_AT, kONE, base, index);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateNow() const {

   return Parser::TimestampLiteral::get(now_);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateDatetime(

     const RexFunctionOperator* rex_function) const {

   CHECK_EQ(size_t(1), rex_function->size());

   const auto arg = translateScalarRex(rex_function->getOperand(0));

   const auto arg_lit = std::dynamic_pointer_cast<Analyzer::Constant>(arg);

   const std::string datetime_err{R"(Only DATETIME('NOW') supported for now.)"};

   if (!arg_lit) {

     throw std::runtime_error(datetime_err);

   }

   CHECK(arg_lit->get_type_info().is_string());

   if (*arg_lit->get_constval().stringval != "NOW"sv) {

     throw std::runtime_error(datetime_err);

   }

   return translateNow();

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateAbs(

     const RexFunctionOperator* rex_function) const {

   std::list<std::pair<std::shared_ptr<Analyzer::Expr>, std::shared_ptr<Analyzer::Expr>>>

       expr_list;

   CHECK_EQ(size_t(1), rex_function->size());

   const auto operand = translateScalarRex(rex_function->getOperand(0));

   const auto& operand_ti = operand->get_type_info();

   CHECK(operand_ti.is_number());

   const auto zero = makeNumericConstant(operand_ti, 0);

   const auto lt_zero = makeExpr<Analyzer::BinOper>(kBOOLEAN, kLT, kONE, operand, zero);

   const auto uminus_operand =

       makeExpr<Analyzer::UOper>(operand_ti.get_type(), kUMINUS, operand);

   expr_list.emplace_back(lt_zero, uminus_operand);

   return makeExpr<Analyzer::CaseExpr>(operand_ti, false, expr_list, operand);

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateSign(

     const RexFunctionOperator* rex_function) const {

   std::list<std::pair<std::shared_ptr<Analyzer::Expr>, std::shared_ptr<Analyzer::Expr>>>

       expr_list;

   CHECK_EQ(size_t(1), rex_function->size());

   const auto operand = translateScalarRex(rex_function->getOperand(0));

   const auto& operand_ti = operand->get_type_info();

   CHECK(operand_ti.is_number());

   const auto zero = makeNumericConstant(operand_ti, 0);

   const auto lt_zero = makeExpr<Analyzer::BinOper>(kBOOLEAN, kLT, kONE, operand, zero);

   expr_list.emplace_back(lt_zero, makeNumericConstant(operand_ti, -1));

   const auto eq_zero = makeExpr<Analyzer::BinOper>(kBOOLEAN, kEQ, kONE, operand, zero);

   expr_list.emplace_back(eq_zero, makeNumericConstant(operand_ti, 0));

   const auto gt_zero = makeExpr<Analyzer::BinOper>(kBOOLEAN, kGT, kONE, operand, zero);

   expr_list.emplace_back(gt_zero, makeNumericConstant(operand_ti, 1));

   return makeExpr<Analyzer::CaseExpr>(

       operand_ti,

       false,

       expr_list,

       makeExpr<Analyzer::Constant>(operand_ti, true, Datum{0}));

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateOffsetInFragment() const {

   return makeExpr<Analyzer::OffsetInFragment>();

 }


 Analyzer::ExpressionPtr RelAlgTranslator::translateArrayFunction(

     const RexFunctionOperator* rex_function) const {

   if (rex_function->getType().get_subtype() == kNULLT) {

     auto sql_type = rex_function->getType();

     CHECK(sql_type.get_type() == kARRAY);


     // FIX-ME:  Deal with NULL arrays

     auto translated_function_args(translateFunctionArgs(rex_function));

     if (translated_function_args.size() > 0) {

       auto const& first_element_logical_type(

           get_logical_type_info(translated_function_args[0]->get_type_info()));


       on_member_of_typeset<kCHAR, kVARCHAR, kTEXT>(

           first_element_logical_type,

           [&] {

             bool same_type_status = true;

             for (auto const& expr_ptr : translated_function_args) {

               same_type_status =

                   same_type_status && (expr_ptr->get_type_info().is_string());

             }


             if (same_type_status == false) {

               throw std::runtime_error(

                   "All elements of the array are not of the same logical subtype; "

                   "consider casting to force this condition.");

             }


             sql_type.set_subtype(first_element_logical_type.get_type());

             sql_type.set_compression(kENCODING_FIXED);

             sql_type.set_comp_param(TRANSIENT_DICT_ID);

           },

           [&] {

             // Non string types

             bool same_type_status = true;

             for (auto const& expr_ptr : translated_function_args) {

               same_type_status =

                   same_type_status && (first_element_logical_type ==

                                        get_logical_type_info(expr_ptr->get_type_info()));

             }


             if (same_type_status == false) {

               throw std::runtime_error(

                   "All elements of the array are not of the same logical subtype; "

                   "consider casting to force this condition.");

             }

             sql_type.set_subtype(first_element_logical_type.get_type());

             sql_type.set_scale(first_element_logical_type.get_scale());

             sql_type.set_precision(first_element_logical_type.get_precision());

           });


       feature_stash_.setCPUOnlyExecutionRequired();

       return makeExpr<Analyzer::ArrayExpr>(

           sql_type, translated_function_args, feature_stash_.getAndBumpArrayExprCount());

     } else {

       throw std::runtime_error("NULL ARRAY[] expressions not supported yet.  FIX-ME.");

     }

   } else {

     feature_stash_.setCPUOnlyExecutionRequired();

     return makeExpr<Analyzer::ArrayExpr>(rex_function->getType(),

                                          translateFunctionArgs(rex_function),

                                          feature_stash_.getAndBumpArrayExprCount());

   }

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateFunction(

     const RexFunctionOperator* rex_function) const {

   if (func_resolve(rex_function->getName(), "LIKE"sv, "PG_ILIKE"sv)) {

     return translateLike(rex_function);

   }

   if (rex_function->getName() == "REGEXP_LIKE"sv) {

     return translateRegexp(rex_function);

   }

   if (rex_function->getName() == "LIKELY"sv) {

     return translateLikely(rex_function);

   }

   if (rex_function->getName() == "UNLIKELY"sv) {

     return translateUnlikely(rex_function);

   }

   if (func_resolve(rex_function->getName(), "PG_EXTRACT"sv, "PG_DATE_TRUNC"sv)) {

     return translateExtract(rex_function);

   }

   if (rex_function->getName() == "DATEADD"sv) {

     return translateDateadd(rex_function);

   }

   if (rex_function->getName() == "DATEDIFF"sv) {

     return translateDatediff(rex_function);

   }

   if (rex_function->getName() == "DATEPART"sv) {

     return translateDatepart(rex_function);

   }

   if (func_resolve(rex_function->getName(), "LENGTH"sv, "CHAR_LENGTH"sv)) {

     return translateLength(rex_function);

   }

   if (rex_function->getName() == "KEY_FOR_STRING"sv) {

     return translateKeyForString(rex_function);

   }

   if (g_enable_experimental_string_functions && rex_function->getName() == "LOWER"sv) {

     return translateLower(rex_function);

   }

   if (func_resolve(rex_function->getName(), "CARDINALITY"sv, "ARRAY_LENGTH"sv)) {

     return translateCardinality(rex_function);

   }

   if (rex_function->getName() == "ITEM"sv) {

     return translateItem(rex_function);

   }

   if (rex_function->getName() == "NOW"sv) {

     return translateNow();

   }

   if (rex_function->getName() == "DATETIME"sv) {

     return translateDatetime(rex_function);

   }

   if (func_resolve(rex_function->getName(), "usTIMESTAMP"sv, "nsTIMESTAMP"sv)) {

     return translateHPTLiteral(rex_function);

   }

   if (rex_function->getName() == "ABS"sv) {

     return translateAbs(rex_function);

   }

   if (rex_function->getName() == "SIGN"sv) {

     return translateSign(rex_function);

   }

   if (func_resolve(rex_function->getName(), "CEIL"sv, "FLOOR"sv)) {

     return makeExpr<Analyzer::FunctionOperWithCustomTypeHandling>(

         rex_function->getType(),

         rex_function->getName(),

         translateFunctionArgs(rex_function));

   } else if (rex_function->getName() == "ROUND"sv) {

     std::vector<std::shared_ptr<Analyzer::Expr>> args =

         translateFunctionArgs(rex_function);


     if (rex_function->size() == 1) {

       // push a 0 constant if 2nd operand is missing.

       // this needs to be done as calcite returns

       // only the 1st operand without defaulting the 2nd one

       // when the user did not specify the 2nd operand.

       SQLTypes t = kSMALLINT;

       Datum d;

       d.smallintval = 0;

       args.push_back(makeExpr<Analyzer::Constant>(t, false, d));

     }


     // make sure we have only 2 operands

     CHECK(args.size() == 2);


     if (!args[0]->get_type_info().is_number()) {

       throw std::runtime_error("Only numeric 1st operands are supported");

     }


     // the 2nd operand does not need to be a constant

     // it can happily reference another integer column

     if (!args[1]->get_type_info().is_integer()) {

       throw std::runtime_error("Only integer 2nd operands are supported");

     }


     // Calcite may upcast decimals in a way that is

     // incompatible with the extension function input. Play it safe and stick with the

     // argument type instead.

     const SQLTypeInfo ret_ti = args[0]->get_type_info().is_decimal()

                                    ? args[0]->get_type_info()

                                    : rex_function->getType();


     return makeExpr<Analyzer::FunctionOperWithCustomTypeHandling>(

         ret_ti, rex_function->getName(), args);

   }

   if (rex_function->getName() == "DATETIME_PLUS"sv) {

     auto dt_plus = makeExpr<Analyzer::FunctionOper>(rex_function->getType(),

                                                     rex_function->getName(),

                                                     translateFunctionArgs(rex_function));

     const auto date_trunc = rewrite_to_date_trunc(dt_plus.get());

     if (date_trunc) {

       return date_trunc;

     }

     return translateDateadd(rex_function);

   }

   if (rex_function->getName() == "/INT"sv) {

     CHECK_EQ(size_t(2), rex_function->size());

     std::shared_ptr<Analyzer::Expr> lhs = translateScalarRex(rex_function->getOperand(0));

     std::shared_ptr<Analyzer::Expr> rhs = translateScalarRex(rex_function->getOperand(1));

     const auto rhs_lit = std::dynamic_pointer_cast<Analyzer::Constant>(rhs);

     return Parser::OperExpr::normalize(kDIVIDE, kONE, lhs, rhs);

   }

   if (rex_function->getName() == "Reinterpret"sv) {

     CHECK_EQ(size_t(1), rex_function->size());

     return translateScalarRex(rex_function->getOperand(0));

   }

   if (func_resolve(rex_function->getName(),

                    "ST_X"sv,

                    "ST_Y"sv,

                    "ST_XMin"sv,

                    "ST_YMin"sv,

                    "ST_XMax"sv,

                    "ST_YMax"sv,

                    "ST_NRings"sv,

                    "ST_NPoints"sv,

                    "ST_Length"sv,

                    "ST_Perimeter"sv,

                    "ST_Area"sv,

                    "ST_SRID"sv,

                    "MapD_GeoPolyBoundsPtr"sv /* deprecated */,

                    "MapD_GeoPolyBoundsPtr"sv /* deprecated */,

                    "OmniSci_Geo_PolyBoundsPtr"sv,

                    "OmniSci_Geo_PolyRenderGroup"sv)) {

     CHECK_EQ(rex_function->size(), size_t(1));

     return translateUnaryGeoFunction(rex_function);

   }

   if (func_resolve(rex_function->getName(),

                    "convert_meters_to_pixel_width"sv,

                    "convert_meters_to_pixel_height"sv,

                    "is_point_in_view"sv,

                    "is_point_size_in_view"sv)) {

     return translateFunctionWithGeoArg(rex_function);

   }

   if (func_resolve(rex_function->getName(),

                    "ST_Distance"sv,

                    "ST_MaxDistance"sv,

                    "ST_Intersects"sv,

                    "ST_Disjoint"sv,

                    "ST_Contains"sv,

                    "ST_Within"sv)) {

     CHECK_EQ(rex_function->size(), size_t(2));

     return translateBinaryGeoFunction(rex_function);

   }

   if (func_resolve(rex_function->getName(), "ST_DWithin"sv, "ST_DFullyWithin"sv)) {

     CHECK_EQ(rex_function->size(), size_t(3));

     return translateTernaryGeoFunction(rex_function);

   }

   if (rex_function->getName() == "OFFSET_IN_FRAGMENT"sv) {

     CHECK_EQ(size_t(0), rex_function->size());

     return translateOffsetInFragment();

   }

   if (rex_function->getName() == "ARRAY"sv) {

     // Var args; currently no check.  Possible fix-me -- can array have 0 elements?

     return translateArrayFunction(rex_function);

   }

   if (func_resolve(rex_function->getName(),

                    "ST_GeomFromText"sv,

                    "ST_GeogFromText"sv,

                    "ST_Point"sv,

                    "ST_SetSRID"sv)) {

     return translateGeoConstructor(rex_function);

   }


   auto arg_expr_list = translateFunctionArgs(rex_function);

   // Reset possibly wrong return type of rex_function to the return

   // type of the optimal valid implementation. The return type can be

   // wrong in the case of multiple implementations of UDF functions

   // that have different return types but Calcite specifies the return

   // type according to the first implementation.

   auto ext_func_sig = bind_function(rex_function->getName(), arg_expr_list);

   auto ret_ti = ext_arg_type_to_type_info(ext_func_sig.getRet());

   // By defualt, the extension function type will not allow nulls. If one of the arguments

   // is nullable, the extension function must also explicitly allow nulls.

   bool arguments_not_null = true;

   for (const auto& arg_expr : arg_expr_list) {

     if (!arg_expr->get_type_info().get_notnull()) {

       arguments_not_null = false;

       break;

     }

   }

   ret_ti.set_notnull(arguments_not_null);

   return makeExpr<Analyzer::FunctionOper>(ret_ti, rex_function->getName(), arg_expr_list);

 }


 namespace {


 std::vector<Analyzer::OrderEntry> translate_collation(

     const std::vector<SortField>& sort_fields) {

   std::vector<Analyzer::OrderEntry> collation;

   for (size_t i = 0; i < sort_fields.size(); ++i) {

     const auto& sort_field = sort_fields[i];

     collation.emplace_back(i,

                            sort_field.getSortDir() == SortDirection::Descending,

                            sort_field.getNullsPosition() == NullSortedPosition::First);

   }

   return collation;

 }


 bool supported_lower_bound(

     const RexWindowFunctionOperator::RexWindowBound& window_bound) {

   return window_bound.unbounded && window_bound.preceding && !window_bound.following &&

          !window_bound.is_current_row && !window_bound.offset &&

          window_bound.order_key == 0;

 }


 bool supported_upper_bound(const RexWindowFunctionOperator* rex_window_function) {

   const auto& window_bound = rex_window_function->getUpperBound();

   const bool to_current_row = !window_bound.unbounded && !window_bound.preceding &&

                               !window_bound.following && window_bound.is_current_row &&

                               !window_bound.offset && window_bound.order_key == 1;

   switch (rex_window_function->getKind()) {

     case SqlWindowFunctionKind::ROW_NUMBER:

     case SqlWindowFunctionKind::RANK:

     case SqlWindowFunctionKind::DENSE_RANK:

     case SqlWindowFunctionKind::CUME_DIST: {

       return to_current_row;

     }

     default: {

       return rex_window_function->getOrderKeys().empty()

                  ? (window_bound.unbounded && !window_bound.preceding &&

                     window_bound.following && !window_bound.is_current_row &&

                     !window_bound.offset && window_bound.order_key == 2)

                  : to_current_row;

     }

   }

 }


 }  // namespace


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateWindowFunction(

     const RexWindowFunctionOperator* rex_window_function) const {

   if (!supported_lower_bound(rex_window_function->getLowerBound()) ||

       !supported_upper_bound(rex_window_function) ||

       ((rex_window_function->getKind() == SqlWindowFunctionKind::ROW_NUMBER) !=

        rex_window_function->isRows())) {

     throw std::runtime_error("Frame specification not supported");

   }

   std::vector<std::shared_ptr<Analyzer::Expr>> args;

   for (size_t i = 0; i < rex_window_function->size(); ++i) {

     args.push_back(translateScalarRex(rex_window_function->getOperand(i)));

   }

   std::vector<std::shared_ptr<Analyzer::Expr>> partition_keys;

   for (const auto& partition_key : rex_window_function->getPartitionKeys()) {

     partition_keys.push_back(translateScalarRex(partition_key.get()));

   }

   std::vector<std::shared_ptr<Analyzer::Expr>> order_keys;

   for (const auto& order_key : rex_window_function->getOrderKeys()) {

     order_keys.push_back(translateScalarRex(order_key.get()));

   }

   auto ti = rex_window_function->getType();

   if (window_function_is_value(rex_window_function->getKind())) {

     CHECK_GE(args.size(), 1u);

     ti = args.front()->get_type_info();

   }

   return makeExpr<Analyzer::WindowFunction>(

       ti,

       rex_window_function->getKind(),

       args,

       partition_keys,

       order_keys,

       translate_collation(rex_window_function->getCollation()));

 }


 Analyzer::ExpressionPtrVector RelAlgTranslator::translateFunctionArgs(

     const RexFunctionOperator* rex_function) const {

   std::vector<std::shared_ptr<Analyzer::Expr>> args;

   for (size_t i = 0; i < rex_function->size(); ++i) {

     args.push_back(translateScalarRex(rex_function->getOperand(i)));

   }

   return args;

 }


 QualsConjunctiveForm qual_to_conjunctive_form(

     const std::shared_ptr<Analyzer::Expr> qual_expr) {

   CHECK(qual_expr);

   auto bin_oper = std::dynamic_pointer_cast<const Analyzer::BinOper>(qual_expr);

   if (!bin_oper) {

     const auto rewritten_qual_expr = rewrite_expr(qual_expr.get());

     return {{}, {rewritten_qual_expr ? rewritten_qual_expr : qual_expr}};

   }


   if (bin_oper->get_optype() == kAND) {

     const auto lhs_cf = qual_to_conjunctive_form(bin_oper->get_own_left_operand());

     const auto rhs_cf = qual_to_conjunctive_form(bin_oper->get_own_right_operand());

     auto simple_quals = lhs_cf.simple_quals;

     simple_quals.insert(

         simple_quals.end(), rhs_cf.simple_quals.begin(), rhs_cf.simple_quals.end());

     auto quals = lhs_cf.quals;

     quals.insert(quals.end(), rhs_cf.quals.begin(), rhs_cf.quals.end());

     return {simple_quals, quals};

   }

   int rte_idx{0};

   const auto simple_qual = bin_oper->normalize_simple_predicate(rte_idx);

   return simple_qual ? QualsConjunctiveForm{{simple_qual}, {}}

                      : QualsConjunctiveForm{{}, {qual_expr}};

 }


 std::vector<std::shared_ptr<Analyzer::Expr>> qual_to_disjunctive_form(

     const std::shared_ptr<Analyzer::Expr>& qual_expr) {

   CHECK(qual_expr);

   const auto bin_oper = std::dynamic_pointer_cast<const Analyzer::BinOper>(qual_expr);

   if (!bin_oper) {

     const auto rewritten_qual_expr = rewrite_expr(qual_expr.get());

     return {rewritten_qual_expr ? rewritten_qual_expr : qual_expr};

   }

   if (bin_oper->get_optype() == kOR) {

     const auto lhs_df = qual_to_disjunctive_form(bin_oper->get_own_left_operand());

     const auto rhs_df = qual_to_disjunctive_form(bin_oper->get_own_right_operand());

     auto quals = lhs_df;

     quals.insert(quals.end(), rhs_df.begin(), rhs_df.end());

     return quals;

   }

   return {qual_expr};

 }


 std::shared_ptr<Analyzer::Expr> RelAlgTranslator::translateHPTLiteral(

     const RexFunctionOperator* rex_function) const {

   /* since calcite uses Avatica package called DateTimeUtils to parse timestamp strings.

      Therefore any string having fractional seconds more 3 places after the decimal

      (milliseconds) will get truncated to 3 decimal places, therefore we lose precision

      (us|ns). Issue: [BE-2461] Here we are hijacking literal cast to Timestamp(6|9) from

      calcite and translating them to generate our own casts.

   */

   CHECK_EQ(size_t(1), rex_function->size());

   const auto operand = translateScalarRex(rex_function->getOperand(0));

   const auto& operand_ti = operand->get_type_info();

   const auto& target_ti = rex_function->getType();

   if (!operand_ti.is_string()) {

     throw std::runtime_error(

         "High precision timestamp cast argument must be a string. Input type is: " +

         operand_ti.get_type_name());

   } else if (!target_ti.is_high_precision_timestamp()) {

     throw std::runtime_error(

         "Cast target type should be high precision timestamp. Input type is: " +

         target_ti.get_type_name());

   } else if (target_ti.get_dimension() != 6 && target_ti.get_dimension() != 9) {

     throw std::runtime_error(

         "Cast target type should be TIMESTAMP(6|9). Input type is: TIMESTAMP(" +

         std::to_string(target_ti.get_dimension()) + ")");

   } else {

     return operand->add_cast(target_ti);

   }

 }

kALL
Definition: sqldefs.h:69

SQLTypeInfoCore::is_boolean
bool is_boolean() const
Definition: sqltypes.h:484

RexCase::getThen
const RexScalar * getThen(const size_t idx) const
Definition: RelAlgAbstractInterpreter.h:366

RelAlgTranslator::join_types_
const std::vector< JoinType > join_types_
Definition: RelAlgTranslator.h:176

SqlWindowFunctionKind::DENSE_RANK

daSECOND
Definition: DateAdd.h:49

SQLAgg
SQLAgg
Definition: sqldefs.h:71

CHECK_EQ
#define CHECK_EQ(x, y)
Definition: Logger.h:198

func_resolve
auto func_resolve
Definition: RelAlgTranslator.h:193

SortDirection::Descending

RelAlgTranslator::translateOffsetInFragment
std::shared_ptr< Analyzer::Expr > translateOffsetInFragment() const
Definition: RelAlgTranslator.cpp:1301

RexWindowFunctionOperator::RexWindowBound::preceding
bool preceding
Definition: RelAlgAbstractInterpreter.h:460

kENCODING_NONE
Definition: sqltypes.h:148

run_benchmark_import.args
tuple args
Definition: run_benchmark_import.py:247

RexAgg::getKind
SQLAgg getKind() const
Definition: RelAlgAbstractInterpreter.h:587

kTIME
Definition: sqltypes.h:52

RelAlgTranslator::translateRegexp
std::shared_ptr< Analyzer::Expr > translateRegexp(const RexFunctionOperator *) const
Definition: RelAlgTranslator.cpp:912

anonymous_namespace{RelAlgTranslator.cpp}::supported_lower_bound
bool supported_lower_bound(const RexWindowFunctionOperator::RexWindowBound &window_bound)
Definition: RelAlgTranslator.cpp:1581

SQLTypes
SQLTypes
Definition: sqltypes.h:41

kENCODING_FIXED
Definition: sqltypes.h:149

kARRAY
Definition: sqltypes.h:57

g_cluster
bool g_cluster

anonymous_namespace{RelAlgTranslator.cpp}::g_max_integer_set_size
const size_t g_max_integer_set_size
Definition: RelAlgTranslator.cpp:579

SqlTypesLayout.h

RexAgg::getOperand
size_t getOperand(size_t idx) const
Definition: RelAlgAbstractInterpreter.h:593

RelAlgTranslator::executor_
const Executor * executor_
Definition: RelAlgTranslator.h:174

RelAlgTranslator::translateUnlikely
std::shared_ptr< Analyzer::Expr > translateUnlikely(const RexFunctionOperator *) const
Definition: RelAlgTranslator.cpp:933

RexCase::getElse
const RexScalar * getElse() const
Definition: RelAlgAbstractInterpreter.h:371

RelAlgTranslator.h

SqlWindowFunctionKind::ROW_NUMBER

DateTimeUtils::get_dateadd_timestamp_precision_scale
constexpr int64_t get_dateadd_timestamp_precision_scale(const DateaddField field)
Definition: DateTimeUtils.h:64

SQLQualifier
SQLQualifier
Definition: sqldefs.h:69

Parser::IntLiteral::analyzeValue
static std::shared_ptr< Analyzer::Expr > analyzeValue(const int64_t intval)
Definition: ParserNode.cpp:112

RelAlgTranslator::translateFunction
std::shared_ptr< Analyzer::Expr > translateFunction(const RexFunctionOperator *) const
Definition: RelAlgTranslator.cpp:1369

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#define LOG(tag)
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