// Copyright (C) 2019-2020 Zilliz. All rights reserved. // // 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 #include #include #include "query/Expr.h" #include "query/Plan.h" #include "query/PlanNode.h" #include "query/generated/ShowPlanNodeVisitor.h" #include "query/generated/ExecExprVisitor.h" #include "segcore/SegmentGrowingImpl.h" #include "test_utils/DataGen.h" using namespace milvus; TEST(Expr, Naive) { SUCCEED(); std::string dsl_string = R"( { "bool": { "must": [ { "term": { "A": [ 1, 2, 5 ] } }, { "range": { "B": { "GT": 1, "LT": 100 } } }, { "vector": { "Vec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10 } } } ] } })"; } TEST(Expr, Range) { SUCCEED(); using namespace milvus; using namespace milvus::query; using namespace milvus::segcore; std::string dsl_string = R"({ "bool": { "must": [ { "range": { "age": { "GT": 1, "LT": 100 } } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; auto schema = std::make_shared(); schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); schema->AddDebugField("age", DataType::INT32); auto plan = CreatePlan(*schema, dsl_string); ShowPlanNodeVisitor shower; Assert(plan->tag2field_.at("$0") == schema->get_field_id(FieldName("fakevec"))); auto out = shower.call_child(*plan->plan_node_); std::cout << out.dump(4); } TEST(Expr, RangeBinary) { SUCCEED(); using namespace milvus; using namespace milvus::query; using namespace milvus::segcore; std::string dsl_string = R"({ "bool": { "must": [ { "range": { "age": { "GT": 1, "LT": 100 } } }, { "vector": { "fakevec": { "metric_type": "Jaccard", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; auto schema = std::make_shared(); schema->AddDebugField("fakevec", DataType::VECTOR_BINARY, 512, MetricType::METRIC_Jaccard); schema->AddDebugField("age", DataType::INT32); auto plan = CreatePlan(*schema, dsl_string); ShowPlanNodeVisitor shower; Assert(plan->tag2field_.at("$0") == schema->get_field_id(FieldName("fakevec"))); auto out = shower.call_child(*plan->plan_node_); std::cout << out.dump(4); } TEST(Expr, InvalidRange) { SUCCEED(); using namespace milvus; using namespace milvus::query; using namespace milvus::segcore; std::string dsl_string = R"( { "bool": { "must": [ { "range": { "age": { "GT": 1, "LT": "100" } } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10 } } } ] } })"; auto schema = std::make_shared(); schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); schema->AddDebugField("age", DataType::INT32); ASSERT_ANY_THROW(CreatePlan(*schema, dsl_string)); } TEST(Expr, InvalidDSL) { SUCCEED(); using namespace milvus; using namespace milvus::query; using namespace milvus::segcore; std::string dsl_string = R"({ "float": { "must": [ { "range": { "age": { "GT": 1, "LT": 100 } } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10 } } } ] } })"; auto schema = std::make_shared(); schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); schema->AddDebugField("age", DataType::INT32); ASSERT_ANY_THROW(CreatePlan(*schema, dsl_string)); } TEST(Expr, ShowExecutor) { using namespace milvus::query; using namespace milvus::segcore; auto node = std::make_unique(); auto schema = std::make_shared(); auto field_id = schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); int64_t num_queries = 100L; auto raw_data = DataGen(schema, num_queries); auto& info = node->search_info_; info.metric_type_ = MetricType::METRIC_L2; info.topk_ = 20; info.field_id_ = field_id; node->predicate_ = std::nullopt; ShowPlanNodeVisitor show_visitor; PlanNodePtr base(node.release()); auto res = show_visitor.call_child(*base); auto dup = res; dup["data"] = "...collased..."; std::cout << dup.dump(4); } TEST(Expr, TestRange) { using namespace milvus::query; using namespace milvus::segcore; std::vector>> testcases = { {R"("GT": 2000, "LT": 3000)", [](int v) { return 2000 < v && v < 3000; }}, {R"("GE": 2000, "LT": 3000)", [](int v) { return 2000 <= v && v < 3000; }}, {R"("GT": 2000, "LE": 3000)", [](int v) { return 2000 < v && v <= 3000; }}, {R"("GE": 2000, "LE": 3000)", [](int v) { return 2000 <= v && v <= 3000; }}, {R"("GE": 2000)", [](int v) { return v >= 2000; }}, {R"("GT": 2000)", [](int v) { return v > 2000; }}, {R"("LE": 2000)", [](int v) { return v <= 2000; }}, {R"("LT": 2000)", [](int v) { return v < 2000; }}, {R"("EQ": 2000)", [](int v) { return v == 2000; }}, {R"("NE": 2000)", [](int v) { return v != 2000; }}, }; std::string dsl_string_tmp = R"({ "bool": { "must": [ { "range": { "age": { @@@@ } } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; auto schema = std::make_shared(); auto vec_fid = schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); auto i64_fid = schema->AddDebugField("age", DataType::INT64); schema->set_primary_field_id(i64_fid); auto seg = CreateGrowingSegment(schema); int N = 1000; std::vector age_col; int num_iters = 100; for (int iter = 0; iter < num_iters; ++iter) { auto raw_data = DataGen(schema, N, iter); auto new_age_col = raw_data.get_col(i64_fid); age_col.insert(age_col.end(), new_age_col.begin(), new_age_col.end()); seg->PreInsert(N); seg->Insert(iter * N, N, raw_data.row_ids_.data(), raw_data.timestamps_.data(), raw_data.raw_); } auto seg_promote = dynamic_cast(seg.get()); ExecExprVisitor visitor(*seg_promote, seg_promote->get_row_count(), MAX_TIMESTAMP); for (auto [clause, ref_func] : testcases) { auto loc = dsl_string_tmp.find("@@@@"); auto dsl_string = dsl_string_tmp; dsl_string.replace(loc, 4, clause); auto plan = CreatePlan(*schema, dsl_string); auto final = visitor.call_child(*plan->plan_node_->predicate_.value()); EXPECT_EQ(final.size(), N * num_iters); for (int i = 0; i < N * num_iters; ++i) { auto ans = final[i]; auto val = age_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } } } TEST(Expr, TestTerm) { using namespace milvus::query; using namespace milvus::segcore; auto vec_2k_3k = [] { std::string buf = "["; for (int i = 2000; i < 3000 - 1; ++i) { buf += std::to_string(i) + ", "; } buf += std::to_string(2999) + "]"; return buf; }(); std::vector>> testcases = { {R"([2000, 3000])", [](int v) { return v == 2000 || v == 3000; }}, {R"([2000])", [](int v) { return v == 2000; }}, {R"([3000])", [](int v) { return v == 3000; }}, {R"([])", [](int v) { return false; }}, {vec_2k_3k, [](int v) { return 2000 <= v && v < 3000; }}, }; std::string dsl_string_tmp = R"({ "bool": { "must": [ { "term": { "age": { "values": @@@@ } } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; auto schema = std::make_shared(); auto vec_fid = schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); auto i64_fid = schema->AddDebugField("age", DataType::INT64); schema->set_primary_field_id(i64_fid); auto seg = CreateGrowingSegment(schema); int N = 1000; std::vector age_col; int num_iters = 100; for (int iter = 0; iter < num_iters; ++iter) { auto raw_data = DataGen(schema, N, iter); auto new_age_col = raw_data.get_col(i64_fid); age_col.insert(age_col.end(), new_age_col.begin(), new_age_col.end()); seg->PreInsert(N); seg->Insert(iter * N, N, raw_data.row_ids_.data(), raw_data.timestamps_.data(), raw_data.raw_); } auto seg_promote = dynamic_cast(seg.get()); ExecExprVisitor visitor(*seg_promote, seg_promote->get_row_count(), MAX_TIMESTAMP); for (auto [clause, ref_func] : testcases) { auto loc = dsl_string_tmp.find("@@@@"); auto dsl_string = dsl_string_tmp; dsl_string.replace(loc, 4, clause); auto plan = CreatePlan(*schema, dsl_string); auto final = visitor.call_child(*plan->plan_node_->predicate_.value()); EXPECT_EQ(final.size(), N * num_iters); for (int i = 0; i < N * num_iters; ++i) { auto ans = final[i]; auto val = age_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } } } TEST(Expr, TestSimpleDsl) { using namespace milvus::query; using namespace milvus::segcore; auto vec_dsl = Json::parse(R"({ "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } })"); int N = 32; auto get_item = [&](int base, int bit = 1) { std::vector terms; // note: random gen range is [0, 2N) for (int i = 0; i < N * 2; ++i) { if (((i >> base) & 0x1) == bit) { terms.push_back(i); } } Json s; s["term"]["age"]["values"] = terms; return s; }; // std::cout << get_item(0).dump(-2); // std::cout << vec_dsl.dump(-2); std::vector>> testcases; { Json dsl; dsl["must"] = Json::array({vec_dsl, get_item(0), get_item(1), get_item(2, 0), get_item(3)}); testcases.emplace_back(dsl, [](int64_t x) { return (x & 0b1111) == 0b1011; }); } { Json dsl; Json sub_dsl; sub_dsl["must"] = Json::array({get_item(0), get_item(1), get_item(2, 0), get_item(3)}); dsl["must"] = Json::array({sub_dsl, vec_dsl}); testcases.emplace_back(dsl, [](int64_t x) { return (x & 0b1111) == 0b1011; }); } { Json dsl; Json sub_dsl; sub_dsl["should"] = Json::array({get_item(0), get_item(1), get_item(2, 0), get_item(3)}); dsl["must"] = Json::array({sub_dsl, vec_dsl}); testcases.emplace_back(dsl, [](int64_t x) { return !!((x & 0b1111) ^ 0b0100); }); } { Json dsl; Json sub_dsl; sub_dsl["must_not"] = Json::array({get_item(0), get_item(1), get_item(2, 0), get_item(3)}); dsl["must"] = Json::array({sub_dsl, vec_dsl}); testcases.emplace_back(dsl, [](int64_t x) { return (x & 0b1111) != 0b1011; }); } auto schema = std::make_shared(); auto vec_fid = schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); auto i64_fid = schema->AddDebugField("age", DataType::INT64); schema->set_primary_field_id(i64_fid); auto seg = CreateGrowingSegment(schema); std::vector age_col; int num_iters = 100; for (int iter = 0; iter < num_iters; ++iter) { auto raw_data = DataGen(schema, N, iter); auto new_age_col = raw_data.get_col(i64_fid); age_col.insert(age_col.end(), new_age_col.begin(), new_age_col.end()); seg->PreInsert(N); seg->Insert(iter * N, N, raw_data.row_ids_.data(), raw_data.timestamps_.data(), raw_data.raw_); } auto seg_promote = dynamic_cast(seg.get()); ExecExprVisitor visitor(*seg_promote, seg_promote->get_row_count(), MAX_TIMESTAMP); for (auto [clause, ref_func] : testcases) { Json dsl; dsl["bool"] = clause; // std::cout << dsl.dump(2); auto plan = CreatePlan(*schema, dsl.dump()); auto final = visitor.call_child(*plan->plan_node_->predicate_.value()); EXPECT_EQ(final.size(), N * num_iters); for (int i = 0; i < N * num_iters; ++i) { bool ans = final[i]; auto val = age_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } } } TEST(Expr, TestCompare) { using namespace milvus::query; using namespace milvus::segcore; std::vector>> testcases = { {R"("LT")", [](int a, int64_t b) { return a < b; }}, {R"("LE")", [](int a, int64_t b) { return a <= b; }}, {R"("GT")", [](int a, int64_t b) { return a > b; }}, {R"("GE")", [](int a, int64_t b) { return a >= b; }}, {R"("EQ")", [](int a, int64_t b) { return a == b; }}, {R"("NE")", [](int a, int64_t b) { return a != b; }}, }; std::string dsl_string_tpl = R"({ "bool": { "must": [ { "compare": { %1%: [ "age1", "age2" ] } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; auto schema = std::make_shared(); auto vec_fid = schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); auto i32_fid = schema->AddDebugField("age1", DataType::INT32); auto i64_fid = schema->AddDebugField("age2", DataType::INT64); schema->set_primary_field_id(i64_fid); auto seg = CreateGrowingSegment(schema); int N = 1000; std::vector age1_col; std::vector age2_col; int num_iters = 100; for (int iter = 0; iter < num_iters; ++iter) { auto raw_data = DataGen(schema, N, iter); auto new_age1_col = raw_data.get_col(i32_fid); auto new_age2_col = raw_data.get_col(i64_fid); age1_col.insert(age1_col.end(), new_age1_col.begin(), new_age1_col.end()); age2_col.insert(age2_col.end(), new_age2_col.begin(), new_age2_col.end()); seg->PreInsert(N); seg->Insert(iter * N, N, raw_data.row_ids_.data(), raw_data.timestamps_.data(), raw_data.raw_); } auto seg_promote = dynamic_cast(seg.get()); ExecExprVisitor visitor(*seg_promote, seg_promote->get_row_count(), MAX_TIMESTAMP); for (auto [clause, ref_func] : testcases) { auto dsl_string = boost::str(boost::format(dsl_string_tpl) % clause); auto plan = CreatePlan(*schema, dsl_string); // std::cout << ShowPlanNodeVisitor().call_child(*plan->plan_node_) << std::endl; auto final = visitor.call_child(*plan->plan_node_->predicate_.value()); EXPECT_EQ(final.size(), N * num_iters); for (int i = 0; i < N * num_iters; ++i) { auto ans = final[i]; auto val1 = age1_col[i]; auto val2 = age2_col[i]; auto ref = ref_func(val1, val2); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << boost::format("[%1%, %2%]") % val1 % val2; } } } TEST(Expr, TestBinaryArithOpEvalRange) { using namespace milvus::query; using namespace milvus::segcore; std::vector, DataType>> testcases = { // Add test cases for BinaryArithOpEvalRangeExpr EQ of various data types {R"("EQ": { "ADD": { "right_operand": 4, "value": 8 } })", [](int8_t v) { return (v + 4) == 8; }, DataType::INT8}, {R"("EQ": { "SUB": { "right_operand": 500, "value": 1500 } })", [](int16_t v) { return (v - 500) == 1500; }, DataType::INT16}, {R"("EQ": { "MUL": { "right_operand": 2, "value": 4000 } })", [](int32_t v) { return (v * 2) == 4000; }, DataType::INT32}, {R"("EQ": { "DIV": { "right_operand": 2, "value": 1000 } })", [](int64_t v) { return (v / 2) == 1000; }, DataType::INT64}, {R"("EQ": { "MOD": { "right_operand": 100, "value": 0 } })", [](int32_t v) { return (v % 100) == 0; }, DataType::INT32}, {R"("EQ": { "ADD": { "right_operand": 500, "value": 2500 } })", [](float v) { return (v + 500) == 2500; }, DataType::FLOAT}, {R"("EQ": { "ADD": { "right_operand": 500, "value": 2500 } })", [](double v) { return (v + 500) == 2500; }, DataType::DOUBLE}, // Add test cases for BinaryArithOpEvalRangeExpr NE of various data types {R"("NE": { "ADD": { "right_operand": 500, "value": 2500 } })", [](float v) { return (v + 500) != 2500; }, DataType::FLOAT}, {R"("NE": { "SUB": { "right_operand": 500, "value": 2500 } })", [](double v) { return (v - 500) != 2500; }, DataType::DOUBLE}, {R"("NE": { "MUL": { "right_operand": 2, "value": 2 } })", [](int8_t v) { return (v * 2) != 2; }, DataType::INT8}, {R"("NE": { "DIV": { "right_operand": 2, "value": 1000 } })", [](int16_t v) { return (v / 2) != 1000; }, DataType::INT16}, {R"("NE": { "MOD": { "right_operand": 100, "value": 0 } })", [](int32_t v) { return (v % 100) != 0; }, DataType::INT32}, {R"("NE": { "ADD": { "right_operand": 500, "value": 2500 } })", [](int64_t v) { return (v + 500) != 2500; }, DataType::INT64}, }; std::string dsl_string_tmp = R"({ "bool": { "must": [ { "range": { @@@@@ } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; std::string dsl_string_int8 = R"( "age8": { @@@@ })"; std::string dsl_string_int16 = R"( "age16": { @@@@ })"; std::string dsl_string_int32 = R"( "age32": { @@@@ })"; std::string dsl_string_int64 = R"( "age64": { @@@@ })"; std::string dsl_string_float = R"( "age_float": { @@@@ })"; std::string dsl_string_double = R"( "age_double": { @@@@ })"; auto schema = std::make_shared(); auto vec_fid = schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); auto i8_fid = schema->AddDebugField("age8", DataType::INT8); auto i16_fid = schema->AddDebugField("age16", DataType::INT16); auto i32_fid = schema->AddDebugField("age32", DataType::INT32); auto i64_fid = schema->AddDebugField("age64", DataType::INT64); auto float_fid = schema->AddDebugField("age_float", DataType::FLOAT); auto double_fid = schema->AddDebugField("age_double", DataType::DOUBLE); schema->set_primary_field_id(i64_fid); auto seg = CreateGrowingSegment(schema); int N = 1000; std::vector age8_col; std::vector age16_col; std::vector age32_col; std::vector age64_col; std::vector age_float_col; std::vector age_double_col; int num_iters = 100; for (int iter = 0; iter < num_iters; ++iter) { auto raw_data = DataGen(schema, N, iter); auto new_age8_col = raw_data.get_col(i8_fid); auto new_age16_col = raw_data.get_col(i16_fid); auto new_age32_col = raw_data.get_col(i32_fid); auto new_age64_col = raw_data.get_col(i64_fid); auto new_age_float_col = raw_data.get_col(float_fid); auto new_age_double_col = raw_data.get_col(double_fid); age8_col.insert(age8_col.end(), new_age8_col.begin(), new_age8_col.end()); age16_col.insert(age16_col.end(), new_age16_col.begin(), new_age16_col.end()); age32_col.insert(age32_col.end(), new_age32_col.begin(), new_age32_col.end()); age64_col.insert(age64_col.end(), new_age64_col.begin(), new_age64_col.end()); age_float_col.insert(age_float_col.end(), new_age_float_col.begin(), new_age_float_col.end()); age_double_col.insert(age_double_col.end(), new_age_double_col.begin(), new_age_double_col.end()); seg->PreInsert(N); seg->Insert(iter * N, N, raw_data.row_ids_.data(), raw_data.timestamps_.data(), raw_data.raw_); } auto seg_promote = dynamic_cast(seg.get()); ExecExprVisitor visitor(*seg_promote, seg_promote->get_row_count(), MAX_TIMESTAMP); for (auto [clause, ref_func, dtype] : testcases) { auto loc = dsl_string_tmp.find("@@@@@"); auto dsl_string = dsl_string_tmp; if (dtype == DataType::INT8) { dsl_string.replace(loc, 5, dsl_string_int8); } else if (dtype == DataType::INT16) { dsl_string.replace(loc, 5, dsl_string_int16); } else if (dtype == DataType::INT32) { dsl_string.replace(loc, 5, dsl_string_int32); } else if (dtype == DataType::INT64) { dsl_string.replace(loc, 5, dsl_string_int64); } else if (dtype == DataType::FLOAT) { dsl_string.replace(loc, 5, dsl_string_float); } else if (dtype == DataType::DOUBLE) { dsl_string.replace(loc, 5, dsl_string_double); } else { ASSERT_TRUE(false) << "No test case defined for this data type"; } loc = dsl_string.find("@@@@"); dsl_string.replace(loc, 4, clause); auto plan = CreatePlan(*schema, dsl_string); auto final = visitor.call_child(*plan->plan_node_->predicate_.value()); EXPECT_EQ(final.size(), N * num_iters); for (int i = 0; i < N * num_iters; ++i) { auto ans = final[i]; if (dtype == DataType::INT8) { auto val = age8_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } else if (dtype == DataType::INT16) { auto val = age16_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } else if (dtype == DataType::INT32) { auto val = age32_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } else if (dtype == DataType::INT64) { auto val = age64_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } else if (dtype == DataType::FLOAT) { auto val = age_float_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } else if (dtype == DataType::DOUBLE) { auto val = age_double_col[i]; auto ref = ref_func(val); ASSERT_EQ(ans, ref) << clause << "@" << i << "!!" << val; } else { ASSERT_TRUE(false) << "No test case defined for this data type"; } } } } TEST(Expr, TestBinaryArithOpEvalRangeExceptions) { using namespace milvus::query; using namespace milvus::segcore; std::vector> testcases = { // Add test for data type mismatch {R"("EQ": { "ADD": { "right_operand": 500, "value": 2500.00 } })", "Assert \"(value.is_number_integer())\"", DataType::INT32}, {R"("EQ": { "ADD": { "right_operand": 500.0, "value": 2500 } })", "Assert \"(right_operand.is_number_integer())\"", DataType::INT32}, {R"("EQ": { "ADD": { "right_operand": 500.0, "value": true } })", "Assert \"(value.is_number())\"", DataType::FLOAT}, {R"("EQ": { "ADD": { "right_operand": "500", "value": 2500.0 } })", "Assert \"(right_operand.is_number())\"", DataType::FLOAT}, // Check unsupported arithmetic operator type {R"("EQ": { "EXP": { "right_operand": 500, "value": 2500 } })", "arith op(exp) not found", DataType::INT32}, // Check unsupported data type {R"("EQ": { "ADD": { "right_operand": true, "value": false } })", "bool type is not supported", DataType::BOOL}, }; std::string dsl_string_tmp = R"({ "bool": { "must": [ { "range": { @@@@@ } }, { "vector": { "fakevec": { "metric_type": "L2", "params": { "nprobe": 10 }, "query": "$0", "topk": 10, "round_decimal": 3 } } } ] } })"; std::string dsl_string_int = R"( "age": { @@@@ })"; std::string dsl_string_num = R"( "FloatN": { @@@@ })"; std::string dsl_string_bool = R"( "BoolField": { @@@@ })"; auto schema = std::make_shared(); schema->AddDebugField("fakevec", DataType::VECTOR_FLOAT, 16, MetricType::METRIC_L2); schema->AddDebugField("age", DataType::INT32); schema->AddDebugField("FloatN", DataType::FLOAT); schema->AddDebugField("BoolField", DataType::BOOL); for (auto [clause, assert_info, dtype] : testcases) { auto loc = dsl_string_tmp.find("@@@@@"); auto dsl_string = dsl_string_tmp; if (dtype == DataType::INT32) { dsl_string.replace(loc, 5, dsl_string_int); } else if (dtype == DataType::FLOAT) { dsl_string.replace(loc, 5, dsl_string_num); } else if (dtype == DataType::BOOL) { dsl_string.replace(loc, 5, dsl_string_bool); } else { ASSERT_TRUE(false) << "No test case defined for this data type"; } loc = dsl_string.find("@@@@"); dsl_string.replace(loc, 4, clause); try { auto plan = CreatePlan(*schema, dsl_string); FAIL() << "Expected AssertionError: " << assert_info << " not thrown"; } catch (const std::exception& err) { std::string err_msg = err.what(); ASSERT_TRUE(err_msg.find(assert_info) != std::string::npos); } catch (...) { FAIL() << "Expected AssertionError: " << assert_info << " not thrown"; } } }