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66487a6dce
memgraph/tests/unit/cypher_main_visitor.cpp
Gareth Andrew Lloyd 3cc2bc2791
Refactor interpreter to support multiple distributed clocks (Part 1) (#1281) 
* Interpreter transaction ID decoupled from storage transaction ID
* Transactional scope for indices, statistics and constraints
* Storage::Accessor now has 2 modes (unique and shared)
* Introduced ResourceLock to fix pthread mutex problems
* Split InfoQuery in two: non-transactional SystemInfoQuery and transactional DatabaseInfoQuery
* Replicable and durable statistics
* Bumped WAL/Snapshot versions
* Initial implementation of the Lamport clock

---------

Co-authored-by: Andreja Tonev <andreja.tonev@memgraph.io>
2023-10-05 16:58:39 +02:00

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// Copyright 2023 Memgraph Ltd.
//
// Use of this software is governed by the Business Source License
// included in the file licenses/BSL.txt; by using this file, you agree to be bound by the terms of the Business Source
// License, and you may not use this file except in compliance with the Business Source License.
//
// As of the Change Date specified in that file, in accordance with
// the Business Source License, use of this software will be governed
// by the Apache License, Version 2.0, included in the file
// licenses/APL.txt.
#include <algorithm>
#include <climits>
#include <limits>
#include <optional>
#include <string>
#include <unordered_map>
#include <variant>
#include <vector>
//////////////////////////////////////////////////////
// "json.hpp" should always come before "antlr4-runtime.h"
// "json.hpp" uses libc's EOF macro while
// "antlr4-runtime.h" contains a static variable of the
// same name, EOF.
// This hides the definition of the macro which causes
// the compilation to fail.
#include <json/json.hpp>
//////////////////////////////////////////////////////
#include <antlr4-runtime.h>
#include <gmock/gmock-matchers.h>
#include <gmock/gmock.h>
#include <gtest/gtest.h>
#include "query/exceptions.hpp"
#include "query/frontend/ast/ast.hpp"
#include "query/frontend/ast/cypher_main_visitor.hpp"
#include "query/frontend/opencypher/parser.hpp"
#include "query/frontend/stripped.hpp"
#include "query/procedure/cypher_types.hpp"
#include "query/procedure/mg_procedure_impl.hpp"
#include "query/procedure/module.hpp"
#include "query/typed_value.hpp"
#include "utils/string.hpp"
#include "utils/variant_helpers.hpp"
using namespace memgraph::query;
using namespace memgraph::query::frontend;
using memgraph::query::TypedValue;
using testing::ElementsAre;
using testing::Pair;
using testing::UnorderedElementsAre;
// Base class for all test types
class Base {
public:
ParsingContext context_;
Parameters parameters_;
virtual ~Base() {}
virtual Query *ParseQuery(const std::string &query_string) = 0;
virtual PropertyIx Prop(const std::string &prop_name) = 0;
virtual LabelIx Label(const std::string &label_name) = 0;
virtual EdgeTypeIx EdgeType(const std::string &edge_type_name) = 0;
TypedValue LiteralValue(Expression *expression) {
if (context_.is_query_cached) {
auto *param_lookup = dynamic_cast<ParameterLookup *>(expression);
return TypedValue(parameters_.AtTokenPosition(param_lookup->token_position_));
} else {
auto *literal = dynamic_cast<PrimitiveLiteral *>(expression);
return TypedValue(literal->value_);
}
}
TypedValue GetLiteral(Expression *expression, const bool use_parameter_lookup,
const std::optional<int> &token_position = std::nullopt) const {
if (use_parameter_lookup) {
auto *param_lookup = dynamic_cast<ParameterLookup *>(expression);
if (param_lookup == nullptr) {
ADD_FAILURE();
return {};
}
if (token_position) {
EXPECT_EQ(param_lookup->token_position_, *token_position);
}
return TypedValue(parameters_.AtTokenPosition(param_lookup->token_position_));
}
auto *literal = dynamic_cast<PrimitiveLiteral *>(expression);
if (literal == nullptr) {
ADD_FAILURE();
return {};
}
if (token_position) {
EXPECT_EQ(literal->token_position_, *token_position);
}
return TypedValue(literal->value_);
}
template <class TValue>
void CheckLiteral(Expression *expression, const TValue &expected,
const std::optional<int> &token_position = std::nullopt) const {
TypedValue expected_tv(expected);
const auto use_parameter_lookup = !expected_tv.IsNull() && context_.is_query_cached;
TypedValue value = GetLiteral(expression, use_parameter_lookup, token_position);
EXPECT_TRUE(TypedValue::BoolEqual{}(value, expected_tv));
}
};
// This generator uses ast constructed by parsing the query.
class AstGenerator : public Base {
public:
Query *ParseQuery(const std::string &query_string) override {
::frontend::opencypher::Parser parser(query_string);
CypherMainVisitor visitor(context_, &ast_storage_);
visitor.visit(parser.tree());
return visitor.query();
}
PropertyIx Prop(const std::string &prop_name) override { return ast_storage_.GetPropertyIx(prop_name); }
LabelIx Label(const std::string &name) override { return ast_storage_.GetLabelIx(name); }
EdgeTypeIx EdgeType(const std::string &name) override { return ast_storage_.GetEdgeTypeIx(name); }
AstStorage ast_storage_;
};
// This clones ast, but uses original one. This done just to ensure that cloning
// doesn't change original.
class OriginalAfterCloningAstGenerator : public AstGenerator {
public:
Query *ParseQuery(const std::string &query_string) override {
auto *original_query = AstGenerator::ParseQuery(query_string);
AstStorage storage;
original_query->Clone(&storage);
return original_query;
}
};
// This generator clones parsed ast and uses that one.
// Original ast is cleared after cloning to ensure that cloned ast doesn't reuse
// any data from original ast.
class ClonedAstGenerator : public Base {
public:
Query *ParseQuery(const std::string &query_string) override {
::frontend::opencypher::Parser parser(query_string);
AstStorage tmp_storage;
{
// Add a label, property and edge type into temporary storage so
// indices have to change in cloned AST.
tmp_storage.GetLabelIx("jkfdklajfkdalsj");
tmp_storage.GetPropertyIx("fdjakfjdklfjdaslk");
tmp_storage.GetEdgeTypeIx("fdjkalfjdlkajfdkla");
}
CypherMainVisitor visitor(context_, &tmp_storage);
visitor.visit(parser.tree());
return visitor.query()->Clone(&ast_storage_);
}
PropertyIx Prop(const std::string &prop_name) override { return ast_storage_.GetPropertyIx(prop_name); }
LabelIx Label(const std::string &name) override { return ast_storage_.GetLabelIx(name); }
EdgeTypeIx EdgeType(const std::string &name) override { return ast_storage_.GetEdgeTypeIx(name); }
AstStorage ast_storage_;
};
// This generator strips ast, clones it and then plugs stripped out literals in
// the same way it is done in ast cacheing in interpreter.
class CachedAstGenerator : public Base {
public:
Query *ParseQuery(const std::string &query_string) override {
context_.is_query_cached = true;
StrippedQuery stripped(query_string);
parameters_ = stripped.literals();
::frontend::opencypher::Parser parser(stripped.query());
AstStorage tmp_storage;
CypherMainVisitor visitor(context_, &tmp_storage);
visitor.visit(parser.tree());
return visitor.query()->Clone(&ast_storage_);
}
PropertyIx Prop(const std::string &prop_name) override { return ast_storage_.GetPropertyIx(prop_name); }
LabelIx Label(const std::string &name) override { return ast_storage_.GetLabelIx(name); }
EdgeTypeIx EdgeType(const std::string &name) override { return ast_storage_.GetEdgeTypeIx(name); }
AstStorage ast_storage_;
};
class MockModule : public procedure::Module {
public:
MockModule(){};
~MockModule() override{};
MockModule(const MockModule &) = delete;
MockModule(MockModule &&) = delete;
MockModule &operator=(const MockModule &) = delete;
MockModule &operator=(MockModule &&) = delete;
bool Close() override { return true; };
const std::map<std::string, mgp_proc, std::less<>> *Procedures() const override { return &procedures; }
const std::map<std::string, mgp_trans, std::less<>> *Transformations() const override { return &transformations; }
const std::map<std::string, mgp_func, std::less<>> *Functions() const override { return &functions; }
std::optional<std::filesystem::path> Path() const override { return std::nullopt; };
std::map<std::string, mgp_proc, std::less<>> procedures{};
std::map<std::string, mgp_trans, std::less<>> transformations{};
std::map<std::string, mgp_func, std::less<>> functions{};
};
void DummyProcCallback(mgp_list * /*args*/, mgp_graph * /*graph*/, mgp_result * /*result*/, mgp_memory * /*memory*/){};
void DummyFuncCallback(mgp_list * /*args*/, mgp_func_context * /*func_ctx*/, mgp_func_result * /*result*/,
mgp_memory * /*memory*/){};
enum class ProcedureType { WRITE, READ };
std::string ToString(const ProcedureType type) { return type == ProcedureType::WRITE ? "write" : "read"; }
class CypherMainVisitorTest : public ::testing::TestWithParam<std::shared_ptr<Base>> {
public:
void SetUp() override {
{
auto mock_module_owner = std::make_unique<MockModule>();
mock_module = mock_module_owner.get();
procedure::gModuleRegistry.RegisterModule("mock_module", std::move(mock_module_owner));
}
{
auto mock_module_with_dots_in_name_owner = std::make_unique<MockModule>();
mock_module_with_dots_in_name = mock_module_with_dots_in_name_owner.get();
procedure::gModuleRegistry.RegisterModule("mock_module.with.dots.in.name",
std::move(mock_module_with_dots_in_name_owner));
}
}
void TearDown() override {
// To release any_type
procedure::gModuleRegistry.UnloadAllModules();
}
static void AddProc(MockModule &module, const char *name, const std::vector<std::string_view> &args,
const std::vector<std::string_view> &results, const ProcedureType type) {
memgraph::utils::MemoryResource *memory = memgraph::utils::NewDeleteResource();
const bool is_write = type == ProcedureType::WRITE;
mgp_proc proc(name, DummyProcCallback, memory, {.is_write = is_write});
for (const auto arg : args) {
proc.args.emplace_back(memgraph::utils::pmr::string{arg, memory}, &any_type);
}
for (const auto result : results) {
proc.results.emplace(memgraph::utils::pmr::string{result, memory}, std::make_pair(&any_type, false));
}
module.procedures.emplace(name, std::move(proc));
}
static void AddFunc(MockModule &module, const char *name, const std::vector<std::string_view> &args) {
memgraph::utils::MemoryResource *memory = memgraph::utils::NewDeleteResource();
mgp_func func(name, DummyFuncCallback, memory);
for (const auto arg : args) {
func.args.emplace_back(memgraph::utils::pmr::string{arg, memory}, &any_type);
}
module.functions.emplace(name, std::move(func));
}
std::string CreateProcByType(const ProcedureType type, const std::vector<std::string_view> &args) {
const auto proc_name = std::string{"proc_"} + ToString(type);
SCOPED_TRACE(proc_name);
AddProc(*mock_module, proc_name.c_str(), {}, args, type);
return std::string{"mock_module."} + proc_name;
}
static const procedure::AnyType any_type;
MockModule *mock_module{nullptr};
MockModule *mock_module_with_dots_in_name{nullptr};
};
const procedure::AnyType CypherMainVisitorTest::any_type{};
std::shared_ptr<Base> gAstGeneratorTypes[] = {
std::make_shared<AstGenerator>(),
std::make_shared<OriginalAfterCloningAstGenerator>(),
std::make_shared<ClonedAstGenerator>(),
std::make_shared<CachedAstGenerator>(),
};
INSTANTIATE_TEST_CASE_P(AstGeneratorTypes, CypherMainVisitorTest, ::testing::ValuesIn(gAstGeneratorTypes));
// NOTE: The above used to use *Typed Tests* functionality of gtest library.
// Unfortunately, the compilation time of this test increased to full 2 minutes!
// Although using Typed Tests is the recommended way to achieve what we want, we
// are (ab)using *Value-Parameterized Tests* functionality instead. This cuts
// down the compilation time to about 20 seconds. The original code is here for
// future reference in case someone gets the idea to change to *appropriate*
// Typed Tests mechanism and ruin the compilation times.
//
// typedef ::testing::Types<AstGenerator, OriginalAfterCloningAstGenerator,
// ClonedAstGenerator, CachedAstGenerator>
// AstGeneratorTypes;
//
// TYPED_TEST_CASE(CypherMainVisitorTest, AstGeneratorTypes);
TEST_P(CypherMainVisitorTest, SyntaxException) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("CREATE ()-[*1....2]-()"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, SyntaxExceptionOnTrailingText) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN 2 + 2 mirko"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, PropertyLookup) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN n.x"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *property_lookup = dynamic_cast<PropertyLookup *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(property_lookup->expression_);
auto identifier = dynamic_cast<Identifier *>(property_lookup->expression_);
ASSERT_TRUE(identifier);
ASSERT_EQ(identifier->name_, "n");
ASSERT_EQ(property_lookup->property_, ast_generator.Prop("x"));
}
TEST_P(CypherMainVisitorTest, LabelsTest) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN n:x:y"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *labels_test = dynamic_cast<LabelsTest *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(labels_test->expression_);
auto identifier = dynamic_cast<Identifier *>(labels_test->expression_);
ASSERT_TRUE(identifier);
ASSERT_EQ(identifier->name_, "n");
ASSERT_THAT(labels_test->labels_, ElementsAre(ast_generator.Label("x"), ast_generator.Label("y")));
}
TEST_P(CypherMainVisitorTest, EscapedLabel) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN n:`l-$\"'ab``e````l`"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *labels_test = dynamic_cast<LabelsTest *>(return_clause->body_.named_expressions[0]->expression_);
auto identifier = dynamic_cast<Identifier *>(labels_test->expression_);
ASSERT_EQ(identifier->name_, "n");
ASSERT_THAT(labels_test->labels_, ElementsAre(ast_generator.Label("l-$\"'ab`e``l")));
}
TEST_P(CypherMainVisitorTest, KeywordLabel) {
for (const auto &label : {"DeLete", "UsER"}) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(fmt::format("RETURN n:{}", label)));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *labels_test = dynamic_cast<LabelsTest *>(return_clause->body_.named_expressions[0]->expression_);
auto identifier = dynamic_cast<Identifier *>(labels_test->expression_);
ASSERT_EQ(identifier->name_, "n");
ASSERT_THAT(labels_test->labels_, ElementsAre(ast_generator.Label(label)));
}
}
TEST_P(CypherMainVisitorTest, HexLetterLabel) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN n:a"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *labels_test = dynamic_cast<LabelsTest *>(return_clause->body_.named_expressions[0]->expression_);
auto identifier = dynamic_cast<Identifier *>(labels_test->expression_);
EXPECT_EQ(identifier->name_, "n");
ASSERT_THAT(labels_test->labels_, ElementsAre(ast_generator.Label("a")));
}
TEST_P(CypherMainVisitorTest, ReturnNoDistinctNoBagSemantics) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.order_by.size(), 0U);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1U);
ASSERT_FALSE(return_clause->body_.limit);
ASSERT_FALSE(return_clause->body_.skip);
ASSERT_FALSE(return_clause->body_.distinct);
}
TEST_P(CypherMainVisitorTest, ReturnDistinct) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN DISTINCT x"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(return_clause->body_.distinct);
}
TEST_P(CypherMainVisitorTest, ReturnLimit) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x LIMIT 5"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(return_clause->body_.limit);
ast_generator.CheckLiteral(return_clause->body_.limit, 5);
}
TEST_P(CypherMainVisitorTest, ReturnSkip) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x SKIP 5"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(return_clause->body_.skip);
ast_generator.CheckLiteral(return_clause->body_.skip, 5);
}
TEST_P(CypherMainVisitorTest, ReturnOrderBy) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x, y, z ORDER BY z ASC, x, y DESC"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_EQ(return_clause->body_.order_by.size(), 3U);
std::vector<std::pair<Ordering, std::string>> ordering;
for (const auto &sort_item : return_clause->body_.order_by) {
auto *identifier = dynamic_cast<Identifier *>(sort_item.expression);
ordering.emplace_back(sort_item.ordering, identifier->name_);
}
ASSERT_THAT(ordering,
UnorderedElementsAre(Pair(Ordering::ASC, "z"), Pair(Ordering::ASC, "x"), Pair(Ordering::DESC, "y")));
}
TEST_P(CypherMainVisitorTest, ReturnNamedIdentifier) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN var AS var5"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
auto *named_expr = return_clause->body_.named_expressions[0];
ASSERT_EQ(named_expr->name_, "var5");
auto *identifier = dynamic_cast<Identifier *>(named_expr->expression_);
ASSERT_EQ(identifier->name_, "var");
}
TEST_P(CypherMainVisitorTest, ReturnAsterisk) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN *"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 0U);
}
TEST_P(CypherMainVisitorTest, IntegerLiteral) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 42"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, 42, 1);
}
TEST_P(CypherMainVisitorTest, IntegerLiteralTooLarge) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN 10000000000000000000000000"), SemanticException);
}
TEST_P(CypherMainVisitorTest, BooleanLiteralTrue) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN TrUe"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, true, 1);
}
TEST_P(CypherMainVisitorTest, BooleanLiteralFalse) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN faLSE"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, false, 1);
}
TEST_P(CypherMainVisitorTest, NullLiteral) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN nULl"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, TypedValue(), 1);
}
TEST_P(CypherMainVisitorTest, ParenthesizedExpression) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN (2)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, 2);
}
TEST_P(CypherMainVisitorTest, OrOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN true Or false oR n"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *or_operator2 = dynamic_cast<OrOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(or_operator2);
auto *or_operator1 = dynamic_cast<OrOperator *>(or_operator2->expression1_);
ASSERT_TRUE(or_operator1);
ast_generator.CheckLiteral(or_operator1->expression1_, true);
ast_generator.CheckLiteral(or_operator1->expression2_, false);
auto *operand3 = dynamic_cast<Identifier *>(or_operator2->expression2_);
ASSERT_TRUE(operand3);
ASSERT_EQ(operand3->name_, "n");
}
TEST_P(CypherMainVisitorTest, XorOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN true xOr false"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *xor_operator = dynamic_cast<XorOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(xor_operator->expression1_, true);
ast_generator.CheckLiteral(xor_operator->expression2_, false);
}
TEST_P(CypherMainVisitorTest, AndOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN true and false"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *and_operator = dynamic_cast<AndOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(and_operator->expression1_, true);
ast_generator.CheckLiteral(and_operator->expression2_, false);
}
TEST_P(CypherMainVisitorTest, AdditionSubtractionOperators) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 1 - 2 + 3"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *addition_operator = dynamic_cast<AdditionOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(addition_operator);
auto *subtraction_operator = dynamic_cast<SubtractionOperator *>(addition_operator->expression1_);
ASSERT_TRUE(subtraction_operator);
ast_generator.CheckLiteral(subtraction_operator->expression1_, 1);
ast_generator.CheckLiteral(subtraction_operator->expression2_, 2);
ast_generator.CheckLiteral(addition_operator->expression2_, 3);
}
TEST_P(CypherMainVisitorTest, MulitplicationOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 2 * 3"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *mult_operator = dynamic_cast<MultiplicationOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(mult_operator->expression1_, 2);
ast_generator.CheckLiteral(mult_operator->expression2_, 3);
}
TEST_P(CypherMainVisitorTest, DivisionOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 2 / 3"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *div_operator = dynamic_cast<DivisionOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(div_operator->expression1_, 2);
ast_generator.CheckLiteral(div_operator->expression2_, 3);
}
TEST_P(CypherMainVisitorTest, ModOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 2 % 3"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *mod_operator = dynamic_cast<ModOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(mod_operator->expression1_, 2);
ast_generator.CheckLiteral(mod_operator->expression2_, 3);
}
#define CHECK_COMPARISON(TYPE, VALUE1, VALUE2) \
do { \
auto *and_operator = dynamic_cast<AndOperator *>(_operator); \
ASSERT_TRUE(and_operator); \
_operator = and_operator->expression1_; \
auto *cmp_operator = dynamic_cast<TYPE *>(and_operator->expression2_); \
ASSERT_TRUE(cmp_operator); \
ast_generator.CheckLiteral(cmp_operator->expression1_, VALUE1); \
ast_generator.CheckLiteral(cmp_operator->expression2_, VALUE2); \
} while (0)
TEST_P(CypherMainVisitorTest, ComparisonOperators) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 2 = 3 != 4 <> 5 < 6 > 7 <= 8 >= 9"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
Expression *_operator = return_clause->body_.named_expressions[0]->expression_;
CHECK_COMPARISON(GreaterEqualOperator, 8, 9);
CHECK_COMPARISON(LessEqualOperator, 7, 8);
CHECK_COMPARISON(GreaterOperator, 6, 7);
CHECK_COMPARISON(LessOperator, 5, 6);
CHECK_COMPARISON(NotEqualOperator, 4, 5);
CHECK_COMPARISON(NotEqualOperator, 3, 4);
auto *cmp_operator = dynamic_cast<EqualOperator *>(_operator);
ASSERT_TRUE(cmp_operator);
ast_generator.CheckLiteral(cmp_operator->expression1_, 2);
ast_generator.CheckLiteral(cmp_operator->expression2_, 3);
}
#undef CHECK_COMPARISON
TEST_P(CypherMainVisitorTest, ListIndexing) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN [1,2,3] [ 2 ]"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *list_index_op = dynamic_cast<SubscriptOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(list_index_op);
auto *list = dynamic_cast<ListLiteral *>(list_index_op->expression1_);
EXPECT_TRUE(list);
ast_generator.CheckLiteral(list_index_op->expression2_, 2);
}
TEST_P(CypherMainVisitorTest, ListSlicingOperatorNoBounds) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN [1,2,3] [ .. ]"), SemanticException);
}
TEST_P(CypherMainVisitorTest, ListSlicingOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN [1,2,3] [ .. 2 ]"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *list_slicing_op = dynamic_cast<ListSlicingOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(list_slicing_op);
auto *list = dynamic_cast<ListLiteral *>(list_slicing_op->list_);
EXPECT_TRUE(list);
EXPECT_FALSE(list_slicing_op->lower_bound_);
ast_generator.CheckLiteral(list_slicing_op->upper_bound_, 2);
}
TEST_P(CypherMainVisitorTest, InListOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 5 IN [1,2]"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *in_list_operator = dynamic_cast<InListOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(in_list_operator);
ast_generator.CheckLiteral(in_list_operator->expression1_, 5);
auto *list = dynamic_cast<ListLiteral *>(in_list_operator->expression2_);
ASSERT_TRUE(list);
}
TEST_P(CypherMainVisitorTest, InWithListIndexing) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 1 IN [[1,2]][0]"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *in_list_operator = dynamic_cast<InListOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(in_list_operator);
ast_generator.CheckLiteral(in_list_operator->expression1_, 1);
auto *list_indexing = dynamic_cast<SubscriptOperator *>(in_list_operator->expression2_);
ASSERT_TRUE(list_indexing);
auto *list = dynamic_cast<ListLiteral *>(list_indexing->expression1_);
EXPECT_TRUE(list);
ast_generator.CheckLiteral(list_indexing->expression2_, 0);
}
TEST_P(CypherMainVisitorTest, CaseGenericForm) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN CASE WHEN n < 10 THEN 1 WHEN n > 10 THEN 2 END"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *if_operator = dynamic_cast<IfOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(if_operator);
auto *condition = dynamic_cast<LessOperator *>(if_operator->condition_);
ASSERT_TRUE(condition);
ast_generator.CheckLiteral(if_operator->then_expression_, 1);
auto *if_operator2 = dynamic_cast<IfOperator *>(if_operator->else_expression_);
ASSERT_TRUE(if_operator2);
auto *condition2 = dynamic_cast<GreaterOperator *>(if_operator2->condition_);
ASSERT_TRUE(condition2);
ast_generator.CheckLiteral(if_operator2->then_expression_, 2);
ast_generator.CheckLiteral(if_operator2->else_expression_, TypedValue());
}
TEST_P(CypherMainVisitorTest, CaseGenericFormElse) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN CASE WHEN n < 10 THEN 1 ELSE 2 END"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *if_operator = dynamic_cast<IfOperator *>(return_clause->body_.named_expressions[0]->expression_);
auto *condition = dynamic_cast<LessOperator *>(if_operator->condition_);
ASSERT_TRUE(condition);
ast_generator.CheckLiteral(if_operator->then_expression_, 1);
ast_generator.CheckLiteral(if_operator->else_expression_, 2);
}
TEST_P(CypherMainVisitorTest, CaseSimpleForm) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN CASE 5 WHEN 10 THEN 1 END"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *if_operator = dynamic_cast<IfOperator *>(return_clause->body_.named_expressions[0]->expression_);
auto *condition = dynamic_cast<EqualOperator *>(if_operator->condition_);
ASSERT_TRUE(condition);
ast_generator.CheckLiteral(condition->expression1_, 5);
ast_generator.CheckLiteral(condition->expression2_, 10);
ast_generator.CheckLiteral(if_operator->then_expression_, 1);
ast_generator.CheckLiteral(if_operator->else_expression_, TypedValue());
}
TEST_P(CypherMainVisitorTest, IsNull) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 2 iS NulL"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *is_type_operator = dynamic_cast<IsNullOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(is_type_operator->expression_, 2);
}
TEST_P(CypherMainVisitorTest, IsNotNull) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 2 iS nOT NulL"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *not_operator = dynamic_cast<NotOperator *>(return_clause->body_.named_expressions[0]->expression_);
auto *is_type_operator = dynamic_cast<IsNullOperator *>(not_operator->expression_);
ast_generator.CheckLiteral(is_type_operator->expression_, 2);
}
TEST_P(CypherMainVisitorTest, NotOperator) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN not true"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *not_operator = dynamic_cast<NotOperator *>(return_clause->body_.named_expressions[0]->expression_);
ast_generator.CheckLiteral(not_operator->expression_, true);
}
TEST_P(CypherMainVisitorTest, UnaryMinusPlusOperators) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN -+5"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *unary_minus_operator =
dynamic_cast<UnaryMinusOperator *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(unary_minus_operator);
auto *unary_plus_operator = dynamic_cast<UnaryPlusOperator *>(unary_minus_operator->expression_);
ASSERT_TRUE(unary_plus_operator);
ast_generator.CheckLiteral(unary_plus_operator->expression_, 5);
}
TEST_P(CypherMainVisitorTest, Aggregation) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("RETURN COUNT(a), MIN(b), MAX(c), SUM(d), AVG(e), COLLECT(f), COUNT(*)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 7U);
Aggregation::Op ops[] = {Aggregation::Op::COUNT, Aggregation::Op::MIN, Aggregation::Op::MAX,
Aggregation::Op::SUM, Aggregation::Op::AVG, Aggregation::Op::COLLECT_LIST};
std::string ids[] = {"a", "b", "c", "d", "e", "f"};
for (int i = 0; i < 6; ++i) {
auto *aggregation = dynamic_cast<Aggregation *>(return_clause->body_.named_expressions[i]->expression_);
ASSERT_TRUE(aggregation);
ASSERT_EQ(aggregation->op_, ops[i]);
auto *identifier = dynamic_cast<Identifier *>(aggregation->expression1_);
ASSERT_TRUE(identifier);
ASSERT_EQ(identifier->name_, ids[i]);
}
auto *aggregation = dynamic_cast<Aggregation *>(return_clause->body_.named_expressions[6]->expression_);
ASSERT_TRUE(aggregation);
ASSERT_EQ(aggregation->op_, Aggregation::Op::COUNT);
ASSERT_FALSE(aggregation->expression1_);
}
TEST_P(CypherMainVisitorTest, UndefinedFunction) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN "
"IHopeWeWillNeverHaveAwesomeMemgraphProcedureWithS"
"uchALongAndAwesomeNameSinceThisTestWouldFail(1)"),
SemanticException);
}
TEST_P(CypherMainVisitorTest, MissingFunction) {
AddFunc(*mock_module, "get", {});
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN missing_function.get()"), SemanticException);
}
TEST_P(CypherMainVisitorTest, Function) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN abs(n, 2)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1);
auto *function = dynamic_cast<Function *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(function);
ASSERT_TRUE(function->function_);
}
TEST_P(CypherMainVisitorTest, MagicFunction) {
AddFunc(*mock_module, "get", {});
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN mock_module.get()"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1);
auto *function = dynamic_cast<Function *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(function);
ASSERT_TRUE(function->function_);
}
TEST_P(CypherMainVisitorTest, StringLiteralDoubleQuotes) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN \"mi'rko\""));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, "mi'rko", 1);
}
TEST_P(CypherMainVisitorTest, StringLiteralSingleQuotes) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 'mi\"rko'"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, "mi\"rko", 1);
}
TEST_P(CypherMainVisitorTest, StringLiteralEscapedChars) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN '\\\\\\'\\\"\\b\\B\\f\\F\\n\\N\\r\\R\\t\\T'"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, "\\'\"\b\b\f\f\n\n\r\r\t\t", 1);
}
TEST_P(CypherMainVisitorTest, StringLiteralEscapedUtf16) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN '\\u221daaa\\u221daaa'"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_,
"\xE2\x88\x9D"
"aaa"
"\xE2\x88\x9D"
"aaa",
1); // u8"\u221daaa\u221daaa"
}
TEST_P(CypherMainVisitorTest, StringLiteralEscapedUtf16Error) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN '\\U221daaa'"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, StringLiteralEscapedUtf32) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN '\\U0001F600aaaa\\U0001F600aaaaaaaa'"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_,
"\xF0\x9F\x98\x80"
"aaaa"
"\xF0\x9F\x98\x80"
"aaaaaaaa",
1); // u8"\U0001F600aaaa\U0001F600aaaaaaaa"
}
TEST_P(CypherMainVisitorTest, DoubleLiteral) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 3.5"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, 3.5, 1);
}
TEST_P(CypherMainVisitorTest, DoubleLiteralExponent) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 5e-1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ast_generator.CheckLiteral(return_clause->body_.named_expressions[0]->expression_, 0.5, 1);
}
TEST_P(CypherMainVisitorTest, ListLiteral) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN [3, [], 'johhny']"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *list_literal = dynamic_cast<ListLiteral *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(list_literal);
ASSERT_EQ(3, list_literal->elements_.size());
ast_generator.CheckLiteral(list_literal->elements_[0], 3);
auto *elem_1 = dynamic_cast<ListLiteral *>(list_literal->elements_[1]);
ASSERT_TRUE(elem_1);
EXPECT_EQ(0, elem_1->elements_.size());
ast_generator.CheckLiteral(list_literal->elements_[2], "johhny");
}
TEST_P(CypherMainVisitorTest, MapLiteral) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN {a: 1, b: 'bla', c: [1, {a: 42}]}"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
auto *map_literal = dynamic_cast<MapLiteral *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(map_literal);
ASSERT_EQ(3, map_literal->elements_.size());
ast_generator.CheckLiteral(map_literal->elements_[ast_generator.Prop("a")], 1);
ast_generator.CheckLiteral(map_literal->elements_[ast_generator.Prop("b")], "bla");
auto *elem_2 = dynamic_cast<ListLiteral *>(map_literal->elements_[ast_generator.Prop("c")]);
ASSERT_TRUE(elem_2);
EXPECT_EQ(2, elem_2->elements_.size());
auto *elem_2_1 = dynamic_cast<MapLiteral *>(elem_2->elements_[1]);
ASSERT_TRUE(elem_2_1);
EXPECT_EQ(1, elem_2_1->elements_.size());
}
TEST_P(CypherMainVisitorTest, MapProjectionLiteral) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(
"WITH {name: \"Morgan\"} as actor, 85 as age RETURN actor {.name, .*, age, lastName: \"Freeman\"}"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[1]);
auto *map_projection_literal =
dynamic_cast<MapProjectionLiteral *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(map_projection_literal);
ASSERT_EQ(4, map_projection_literal->elements_.size());
ASSERT_EQ(std::string(map_projection_literal->elements_[ast_generator.Prop("name")]->GetTypeInfo().name),
std::string("PropertyLookup"));
ASSERT_EQ(std::string(map_projection_literal->elements_[ast_generator.Prop("*")]->GetTypeInfo().name),
std::string("AllPropertiesLookup"));
ASSERT_EQ(std::string(map_projection_literal->elements_[ast_generator.Prop("age")]->GetTypeInfo().name),
std::string("Identifier"));
ASSERT_EQ(std::string(map_projection_literal->elements_[ast_generator.Prop("lastName")]->GetTypeInfo().name),
std::string(typeid(ast_generator).name()).ends_with("CachedAstGenerator")
? std::string("ParameterLookup")
: std::string("PrimitiveLiteral"));
}
TEST_P(CypherMainVisitorTest, MapProjectionRepeatedKeySameTypeValue) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH {} as x RETURN x {a: 0, a: 1}"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[1]);
auto *map_projection_literal =
dynamic_cast<MapProjectionLiteral *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(map_projection_literal);
// When multiple map properties have the same name, only one gets in
ASSERT_EQ(1, map_projection_literal->elements_.size());
}
TEST_P(CypherMainVisitorTest, MapProjectionRepeatedKeyDifferentTypeValue) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH {a: 0} as x, 1 as a RETURN x {a: 2, .a, a}"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[1]);
auto *map_projection_literal =
dynamic_cast<MapProjectionLiteral *>(return_clause->body_.named_expressions[0]->expression_);
ASSERT_TRUE(map_projection_literal);
// When multiple map properties have the same name, only one gets in
ASSERT_EQ(1, map_projection_literal->elements_.size());
// The last-given map property is the one that gets in
ASSERT_EQ(std::string(map_projection_literal->elements_[ast_generator.Prop("a")]->GetTypeInfo().name),
std::string("Identifier"));
}
TEST_P(CypherMainVisitorTest, NodePattern) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (:label1:label2:label3 {a : 5, b : 10}) RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_FALSE(match->optional_);
EXPECT_FALSE(match->where_);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_TRUE(match->patterns_[0]);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 1U);
auto node = dynamic_cast<NodeAtom *>(match->patterns_[0]->atoms_[0]);
ASSERT_TRUE(node);
ASSERT_TRUE(node->identifier_);
EXPECT_EQ(node->identifier_->name_, CypherMainVisitor::kAnonPrefix + std::to_string(1));
EXPECT_FALSE(node->identifier_->user_declared_);
EXPECT_THAT(node->labels_, UnorderedElementsAre(ast_generator.Label("label1"), ast_generator.Label("label2"),
ast_generator.Label("label3")));
std::unordered_map<PropertyIx, int64_t> properties;
for (auto x : std::get<0>(node->properties_)) {
TypedValue value = ast_generator.LiteralValue(x.second);
ASSERT_TRUE(value.type() == TypedValue::Type::Int);
properties[x.first] = value.ValueInt();
}
EXPECT_THAT(properties, UnorderedElementsAre(Pair(ast_generator.Prop("a"), 5), Pair(ast_generator.Prop("b"), 10)));
}
TEST_P(CypherMainVisitorTest, PropertyMapSameKeyAppearsTwice) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("MATCH ({a : 1, a : 2})"), SemanticException);
}
TEST_P(CypherMainVisitorTest, NodePatternIdentifier) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (var) RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_FALSE(match->optional_);
EXPECT_FALSE(match->where_);
auto node = dynamic_cast<NodeAtom *>(match->patterns_[0]->atoms_[0]);
ASSERT_TRUE(node);
ASSERT_TRUE(node->identifier_);
EXPECT_EQ(node->identifier_->name_, "var");
EXPECT_TRUE(node->identifier_->user_declared_);
EXPECT_THAT(node->labels_, UnorderedElementsAre());
EXPECT_THAT(std::get<0>(node->properties_), UnorderedElementsAre());
}
TEST_P(CypherMainVisitorTest, RelationshipPatternNoDetails) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()--() RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_FALSE(match->optional_);
EXPECT_FALSE(match->where_);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_TRUE(match->patterns_[0]);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
auto *node1 = dynamic_cast<NodeAtom *>(match->patterns_[0]->atoms_[0]);
ASSERT_TRUE(node1);
auto *edge = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(edge);
auto *node2 = dynamic_cast<NodeAtom *>(match->patterns_[0]->atoms_[2]);
ASSERT_TRUE(node2);
ASSERT_TRUE(node1->identifier_);
ASSERT_TRUE(edge->identifier_);
ASSERT_TRUE(node2->identifier_);
EXPECT_THAT(
std::vector<std::string>({node1->identifier_->name_, edge->identifier_->name_, node2->identifier_->name_}),
UnorderedElementsAre(CypherMainVisitor::kAnonPrefix + std::to_string(1),
CypherMainVisitor::kAnonPrefix + std::to_string(2),
CypherMainVisitor::kAnonPrefix + std::to_string(3)));
EXPECT_FALSE(node1->identifier_->user_declared_);
EXPECT_FALSE(edge->identifier_->user_declared_);
EXPECT_FALSE(node2->identifier_->user_declared_);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::BOTH);
}
// PatternPart in braces.
TEST_P(CypherMainVisitorTest, PatternPartBraces) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ((()--())) RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_FALSE(match->where_);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_TRUE(match->patterns_[0]);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
auto *node1 = dynamic_cast<NodeAtom *>(match->patterns_[0]->atoms_[0]);
ASSERT_TRUE(node1);
auto *edge = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(edge);
auto *node2 = dynamic_cast<NodeAtom *>(match->patterns_[0]->atoms_[2]);
ASSERT_TRUE(node2);
ASSERT_TRUE(node1->identifier_);
ASSERT_TRUE(edge->identifier_);
ASSERT_TRUE(node2->identifier_);
EXPECT_THAT(
std::vector<std::string>({node1->identifier_->name_, edge->identifier_->name_, node2->identifier_->name_}),
UnorderedElementsAre(CypherMainVisitor::kAnonPrefix + std::to_string(1),
CypherMainVisitor::kAnonPrefix + std::to_string(2),
CypherMainVisitor::kAnonPrefix + std::to_string(3)));
EXPECT_FALSE(node1->identifier_->user_declared_);
EXPECT_FALSE(edge->identifier_->user_declared_);
EXPECT_FALSE(node2->identifier_->user_declared_);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::BOTH);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternDetails) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()<-[:type1|type2 {a : 5, b : 10}]-() RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_FALSE(match->optional_);
EXPECT_FALSE(match->where_);
auto *edge = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::IN);
EXPECT_THAT(edge->edge_types_,
UnorderedElementsAre(ast_generator.EdgeType("type1"), ast_generator.EdgeType("type2")));
std::unordered_map<PropertyIx, int64_t> properties;
for (auto x : std::get<0>(edge->properties_)) {
TypedValue value = ast_generator.LiteralValue(x.second);
ASSERT_TRUE(value.type() == TypedValue::Type::Int);
properties[x.first] = value.ValueInt();
}
EXPECT_THAT(properties, UnorderedElementsAre(Pair(ast_generator.Prop("a"), 5), Pair(ast_generator.Prop("b"), 10)));
}
TEST_P(CypherMainVisitorTest, RelationshipPatternVariable) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[var]->() RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_FALSE(match->optional_);
EXPECT_FALSE(match->where_);
auto *edge = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
ASSERT_TRUE(edge->identifier_);
EXPECT_THAT(edge->identifier_->name_, "var");
EXPECT_TRUE(edge->identifier_->user_declared_);
}
// Assert that match has a single pattern with a single edge atom and store it
// in edge parameter.
void AssertMatchSingleEdgeAtom(Match *match, EdgeAtom *&edge) {
ASSERT_TRUE(match);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
edge = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(edge);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternUnbounded) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
EXPECT_EQ(edge->lower_bound_, nullptr);
EXPECT_EQ(edge->upper_bound_, nullptr);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternLowerBounded) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*42..]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
ast_generator.CheckLiteral(edge->lower_bound_, 42);
EXPECT_EQ(edge->upper_bound_, nullptr);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternUpperBounded) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*..42]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
EXPECT_EQ(edge->lower_bound_, nullptr);
ast_generator.CheckLiteral(edge->upper_bound_, 42);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternLowerUpperBounded) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*24..42]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
ast_generator.CheckLiteral(edge->lower_bound_, 24);
ast_generator.CheckLiteral(edge->upper_bound_, 42);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternFixedRange) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*42]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
ast_generator.CheckLiteral(edge->lower_bound_, 42);
ast_generator.CheckLiteral(edge->upper_bound_, 42);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternFloatingUpperBound) {
// [r*1...2] should be parsed as [r*1..0.2]
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*1...2]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
ast_generator.CheckLiteral(edge->lower_bound_, 1);
ast_generator.CheckLiteral(edge->upper_bound_, 0.2);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternUnboundedWithProperty) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r* {prop: 42}]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
EXPECT_EQ(edge->lower_bound_, nullptr);
EXPECT_EQ(edge->upper_bound_, nullptr);
ast_generator.CheckLiteral(std::get<0>(edge->properties_)[ast_generator.Prop("prop")], 42);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternDotsUnboundedWithEdgeTypeProperty) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r:edge_type*..{prop: 42}]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
EXPECT_EQ(edge->lower_bound_, nullptr);
EXPECT_EQ(edge->upper_bound_, nullptr);
ast_generator.CheckLiteral(std::get<0>(edge->properties_)[ast_generator.Prop("prop")], 42);
ASSERT_EQ(edge->edge_types_.size(), 1U);
auto edge_type = ast_generator.EdgeType("edge_type");
EXPECT_EQ(edge->edge_types_[0], edge_type);
}
TEST_P(CypherMainVisitorTest, RelationshipPatternUpperBoundedWithProperty) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r*..2{prop: 42}]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
EdgeAtom *edge = nullptr;
AssertMatchSingleEdgeAtom(match, edge);
EXPECT_EQ(edge->direction_, EdgeAtom::Direction::OUT);
EXPECT_EQ(edge->type_, EdgeAtom::Type::DEPTH_FIRST);
EXPECT_EQ(edge->lower_bound_, nullptr);
ast_generator.CheckLiteral(edge->upper_bound_, 2);
ast_generator.CheckLiteral(std::get<0>(edge->properties_)[ast_generator.Prop("prop")], 42);
}
// TODO maybe uncomment
// // PatternPart with variable.
// TEST_P(CypherMainVisitorTest, PatternPartVariable) {
// ParserTables parser("CREATE var=()--()");
// ASSERT_EQ(parser.identifiers_map_.size(), 1U);
// ASSERT_EQ(parser.pattern_parts_.size(), 1U);
// ASSERT_EQ(parser.relationships_.size(), 1U);
// ASSERT_EQ(parser.nodes_.size(), 2U);
// ASSERT_EQ(parser.pattern_parts_.begin()->second.nodes.size(), 2U);
// ASSERT_EQ(parser.pattern_parts_.begin()->second.relationships.size(), 1U);
// ASSERT_NE(parser.identifiers_map_.find("var"),
// parser.identifiers_map_.end());
// auto output_identifier = parser.identifiers_map_["var"];
// ASSERT_NE(parser.pattern_parts_.find(output_identifier),
// parser.pattern_parts_.end());
// }
TEST_P(CypherMainVisitorTest, ReturnUnanemdIdentifier) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN var"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(return_clause);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1U);
auto *named_expr = return_clause->body_.named_expressions[0];
ASSERT_TRUE(named_expr);
ASSERT_EQ(named_expr->name_, "var");
auto *identifier = dynamic_cast<Identifier *>(named_expr->expression_);
ASSERT_TRUE(identifier);
ASSERT_EQ(identifier->name_, "var");
ASSERT_TRUE(identifier->user_declared_);
}
TEST_P(CypherMainVisitorTest, Create) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CREATE (n)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *create = dynamic_cast<Create *>(single_query->clauses_[0]);
ASSERT_TRUE(create);
ASSERT_EQ(create->patterns_.size(), 1U);
ASSERT_TRUE(create->patterns_[0]);
ASSERT_EQ(create->patterns_[0]->atoms_.size(), 1U);
auto node = dynamic_cast<NodeAtom *>(create->patterns_[0]->atoms_[0]);
ASSERT_TRUE(node);
ASSERT_TRUE(node->identifier_);
ASSERT_EQ(node->identifier_->name_, "n");
}
TEST_P(CypherMainVisitorTest, Delete) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("DELETE n, m"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *del = dynamic_cast<Delete *>(single_query->clauses_[0]);
ASSERT_TRUE(del);
ASSERT_FALSE(del->detach_);
ASSERT_EQ(del->expressions_.size(), 2U);
auto *identifier1 = dynamic_cast<Identifier *>(del->expressions_[0]);
ASSERT_TRUE(identifier1);
ASSERT_EQ(identifier1->name_, "n");
auto *identifier2 = dynamic_cast<Identifier *>(del->expressions_[1]);
ASSERT_TRUE(identifier2);
ASSERT_EQ(identifier2->name_, "m");
}
TEST_P(CypherMainVisitorTest, DeleteDetach) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("DETACH DELETE n"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *del = dynamic_cast<Delete *>(single_query->clauses_[0]);
ASSERT_TRUE(del);
ASSERT_TRUE(del->detach_);
ASSERT_EQ(del->expressions_.size(), 1U);
auto *identifier1 = dynamic_cast<Identifier *>(del->expressions_[0]);
ASSERT_TRUE(identifier1);
ASSERT_EQ(identifier1->name_, "n");
}
TEST_P(CypherMainVisitorTest, OptionalMatchWhere) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("OPTIONAL MATCH (n) WHERE m RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
EXPECT_TRUE(match->optional_);
ASSERT_TRUE(match->where_);
auto *identifier = dynamic_cast<Identifier *>(match->where_->expression_);
ASSERT_TRUE(identifier);
ASSERT_EQ(identifier->name_, "m");
}
TEST_P(CypherMainVisitorTest, Set) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("SET a.x = b, c = d, e += f, g : h : i "));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 4U);
{
auto *set_property = dynamic_cast<SetProperty *>(single_query->clauses_[0]);
ASSERT_TRUE(set_property);
ASSERT_TRUE(set_property->property_lookup_);
auto *identifier1 = dynamic_cast<Identifier *>(set_property->property_lookup_->expression_);
ASSERT_TRUE(identifier1);
ASSERT_EQ(identifier1->name_, "a");
ASSERT_EQ(set_property->property_lookup_->property_, ast_generator.Prop("x"));
auto *identifier2 = dynamic_cast<Identifier *>(set_property->expression_);
ASSERT_EQ(identifier2->name_, "b");
}
{
auto *set_properties_assignment = dynamic_cast<SetProperties *>(single_query->clauses_[1]);
ASSERT_TRUE(set_properties_assignment);
ASSERT_FALSE(set_properties_assignment->update_);
ASSERT_TRUE(set_properties_assignment->identifier_);
ASSERT_EQ(set_properties_assignment->identifier_->name_, "c");
auto *identifier = dynamic_cast<Identifier *>(set_properties_assignment->expression_);
ASSERT_EQ(identifier->name_, "d");
}
{
auto *set_properties_update = dynamic_cast<SetProperties *>(single_query->clauses_[2]);
ASSERT_TRUE(set_properties_update);
ASSERT_TRUE(set_properties_update->update_);
ASSERT_TRUE(set_properties_update->identifier_);
ASSERT_EQ(set_properties_update->identifier_->name_, "e");
auto *identifier = dynamic_cast<Identifier *>(set_properties_update->expression_);
ASSERT_EQ(identifier->name_, "f");
}
{
auto *set_labels = dynamic_cast<SetLabels *>(single_query->clauses_[3]);
ASSERT_TRUE(set_labels);
ASSERT_TRUE(set_labels->identifier_);
ASSERT_EQ(set_labels->identifier_->name_, "g");
ASSERT_THAT(set_labels->labels_, UnorderedElementsAre(ast_generator.Label("h"), ast_generator.Label("i")));
}
}
TEST_P(CypherMainVisitorTest, Remove) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("REMOVE a.x, g : h : i"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
{
auto *remove_property = dynamic_cast<RemoveProperty *>(single_query->clauses_[0]);
ASSERT_TRUE(remove_property);
ASSERT_TRUE(remove_property->property_lookup_);
auto *identifier1 = dynamic_cast<Identifier *>(remove_property->property_lookup_->expression_);
ASSERT_TRUE(identifier1);
ASSERT_EQ(identifier1->name_, "a");
ASSERT_EQ(remove_property->property_lookup_->property_, ast_generator.Prop("x"));
}
{
auto *remove_labels = dynamic_cast<RemoveLabels *>(single_query->clauses_[1]);
ASSERT_TRUE(remove_labels);
ASSERT_TRUE(remove_labels->identifier_);
ASSERT_EQ(remove_labels->identifier_->name_, "g");
ASSERT_THAT(remove_labels->labels_, UnorderedElementsAre(ast_generator.Label("h"), ast_generator.Label("i")));
}
}
TEST_P(CypherMainVisitorTest, With) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH n AS m RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *with = dynamic_cast<With *>(single_query->clauses_[0]);
ASSERT_TRUE(with);
ASSERT_FALSE(with->body_.distinct);
ASSERT_FALSE(with->body_.limit);
ASSERT_FALSE(with->body_.skip);
ASSERT_EQ(with->body_.order_by.size(), 0U);
ASSERT_FALSE(with->where_);
ASSERT_EQ(with->body_.named_expressions.size(), 1U);
auto *named_expr = with->body_.named_expressions[0];
ASSERT_EQ(named_expr->name_, "m");
auto *identifier = dynamic_cast<Identifier *>(named_expr->expression_);
ASSERT_EQ(identifier->name_, "n");
}
TEST_P(CypherMainVisitorTest, WithNonAliasedExpression) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("WITH n.x RETURN 1"), SemanticException);
}
TEST_P(CypherMainVisitorTest, WithNonAliasedVariable) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH n RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *with = dynamic_cast<With *>(single_query->clauses_[0]);
ASSERT_TRUE(with);
ASSERT_EQ(with->body_.named_expressions.size(), 1U);
auto *named_expr = with->body_.named_expressions[0];
ASSERT_EQ(named_expr->name_, "n");
auto *identifier = dynamic_cast<Identifier *>(named_expr->expression_);
ASSERT_EQ(identifier->name_, "n");
}
TEST_P(CypherMainVisitorTest, WithDistinct) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH DISTINCT n AS m RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *with = dynamic_cast<With *>(single_query->clauses_[0]);
ASSERT_TRUE(with->body_.distinct);
ASSERT_FALSE(with->where_);
ASSERT_EQ(with->body_.named_expressions.size(), 1U);
auto *named_expr = with->body_.named_expressions[0];
ASSERT_EQ(named_expr->name_, "m");
auto *identifier = dynamic_cast<Identifier *>(named_expr->expression_);
ASSERT_EQ(identifier->name_, "n");
}
TEST_P(CypherMainVisitorTest, WithBag) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH n as m ORDER BY m SKIP 1 LIMIT 2 RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *with = dynamic_cast<With *>(single_query->clauses_[0]);
ASSERT_FALSE(with->body_.distinct);
ASSERT_FALSE(with->where_);
ASSERT_EQ(with->body_.named_expressions.size(), 1U);
// No need to check contents of body. That is checked in RETURN clause tests.
ASSERT_EQ(with->body_.order_by.size(), 1U);
ASSERT_TRUE(with->body_.limit);
ASSERT_TRUE(with->body_.skip);
}
TEST_P(CypherMainVisitorTest, WithWhere) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH n AS m WHERE k RETURN 1"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *with = dynamic_cast<With *>(single_query->clauses_[0]);
ASSERT_TRUE(with);
ASSERT_TRUE(with->where_);
auto *identifier = dynamic_cast<Identifier *>(with->where_->expression_);
ASSERT_TRUE(identifier);
ASSERT_EQ(identifier->name_, "k");
ASSERT_EQ(with->body_.named_expressions.size(), 1U);
auto *named_expr = with->body_.named_expressions[0];
ASSERT_EQ(named_expr->name_, "m");
auto *identifier2 = dynamic_cast<Identifier *>(named_expr->expression_);
ASSERT_EQ(identifier2->name_, "n");
}
TEST_P(CypherMainVisitorTest, WithAnonymousVariableCapture) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("WITH 5 as anon1 MATCH () return *"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 3U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[1]);
ASSERT_TRUE(match);
ASSERT_EQ(match->patterns_.size(), 1U);
auto *pattern = match->patterns_[0];
ASSERT_TRUE(pattern);
ASSERT_EQ(pattern->atoms_.size(), 1U);
auto *atom = dynamic_cast<NodeAtom *>(pattern->atoms_[0]);
ASSERT_TRUE(atom);
ASSERT_NE("anon1", atom->identifier_->name_);
}
TEST_P(CypherMainVisitorTest, ClausesOrdering) {
// Obviously some of the ridiculous combinations don't fail here, but they
// will fail in semantic analysis or they make perfect sense as a part of
// bigger query.
auto &ast_generator = *GetParam();
ast_generator.ParseQuery("RETURN 1");
ASSERT_THROW(ast_generator.ParseQuery("RETURN 1 RETURN 1"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 1 MATCH (n) RETURN n"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 1 DELETE n"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 1 MERGE (n)"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 1 WITH n AS m RETURN 1"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 1 AS n UNWIND n AS x RETURN x"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("OPTIONAL MATCH (n) MATCH (m) RETURN n, m"), SemanticException);
ast_generator.ParseQuery("OPTIONAL MATCH (n) WITH n MATCH (m) RETURN n, m");
ast_generator.ParseQuery("OPTIONAL MATCH (n) OPTIONAL MATCH (m) RETURN n, m");
ast_generator.ParseQuery("MATCH (n) OPTIONAL MATCH (m) RETURN n, m");
ast_generator.ParseQuery("CREATE (n)");
ASSERT_THROW(ast_generator.ParseQuery("SET n:x MATCH (n) RETURN n"), SemanticException);
ast_generator.ParseQuery("REMOVE n.x SET n.x = 1");
ast_generator.ParseQuery("REMOVE n:L RETURN n");
ast_generator.ParseQuery("SET n.x = 1 WITH n AS m RETURN m");
ASSERT_THROW(ast_generator.ParseQuery("MATCH (n)"), SemanticException);
ast_generator.ParseQuery("MATCH (n) MATCH (n) RETURN n");
ast_generator.ParseQuery("MATCH (n) SET n = m");
ast_generator.ParseQuery("MATCH (n) RETURN n");
ast_generator.ParseQuery("MATCH (n) WITH n AS m RETURN m");
ASSERT_THROW(ast_generator.ParseQuery("WITH 1 AS n"), SemanticException);
ast_generator.ParseQuery("WITH 1 AS n WITH n AS m RETURN m");
ast_generator.ParseQuery("WITH 1 AS n RETURN n");
ast_generator.ParseQuery("WITH 1 AS n SET n += m");
ast_generator.ParseQuery("WITH 1 AS n MATCH (n) RETURN n");
ASSERT_THROW(ast_generator.ParseQuery("UNWIND [1,2,3] AS x"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("CREATE (n) UNWIND [1,2,3] AS x RETURN x"), SemanticException);
ast_generator.ParseQuery("UNWIND [1,2,3] AS x CREATE (n) RETURN x");
ast_generator.ParseQuery("CREATE (n) WITH n UNWIND [1,2,3] AS x RETURN x");
}
TEST_P(CypherMainVisitorTest, Merge) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MERGE (a) -[:r]- (b) ON MATCH SET a.x = b.x "
"ON CREATE SET b :label ON MATCH SET b = a"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *merge = dynamic_cast<Merge *>(single_query->clauses_[0]);
ASSERT_TRUE(merge);
EXPECT_TRUE(dynamic_cast<Pattern *>(merge->pattern_));
ASSERT_EQ(merge->on_match_.size(), 2U);
EXPECT_TRUE(dynamic_cast<SetProperty *>(merge->on_match_[0]));
EXPECT_TRUE(dynamic_cast<SetProperties *>(merge->on_match_[1]));
ASSERT_EQ(merge->on_create_.size(), 1U);
EXPECT_TRUE(dynamic_cast<SetLabels *>(merge->on_create_[0]));
}
TEST_P(CypherMainVisitorTest, Unwind) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("UNWIND [1,2,3] AS elem RETURN elem"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *unwind = dynamic_cast<Unwind *>(single_query->clauses_[0]);
ASSERT_TRUE(unwind);
auto *ret = dynamic_cast<Return *>(single_query->clauses_[1]);
EXPECT_TRUE(ret);
ASSERT_TRUE(unwind->named_expression_);
EXPECT_EQ(unwind->named_expression_->name_, "elem");
auto *expr = unwind->named_expression_->expression_;
ASSERT_TRUE(expr);
ASSERT_TRUE(dynamic_cast<ListLiteral *>(expr));
}
TEST_P(CypherMainVisitorTest, UnwindWithoutAsError) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("UNWIND [1,2,3] RETURN 42"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, CreateIndex) {
auto &ast_generator = *GetParam();
auto *index_query = dynamic_cast<IndexQuery *>(ast_generator.ParseQuery("Create InDeX oN :mirko(slavko)"));
ASSERT_TRUE(index_query);
EXPECT_EQ(index_query->action_, IndexQuery::Action::CREATE);
EXPECT_EQ(index_query->label_, ast_generator.Label("mirko"));
std::vector<PropertyIx> expected_properties{ast_generator.Prop("slavko")};
EXPECT_EQ(index_query->properties_, expected_properties);
}
TEST_P(CypherMainVisitorTest, DropIndex) {
auto &ast_generator = *GetParam();
auto *index_query = dynamic_cast<IndexQuery *>(ast_generator.ParseQuery("dRoP InDeX oN :mirko(slavko)"));
ASSERT_TRUE(index_query);
EXPECT_EQ(index_query->action_, IndexQuery::Action::DROP);
EXPECT_EQ(index_query->label_, ast_generator.Label("mirko"));
std::vector<PropertyIx> expected_properties{ast_generator.Prop("slavko")};
EXPECT_EQ(index_query->properties_, expected_properties);
}
TEST_P(CypherMainVisitorTest, DropIndexWithoutProperties) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("dRoP InDeX oN :mirko()"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, DropIndexWithMultipleProperties) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("dRoP InDeX oN :mirko(slavko, pero)"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, ReturnAll) {
{
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("RETURN all(x in [1,2,3])"), SyntaxException);
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN all(x IN [1,2,3] WHERE x = 2)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *ret = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(ret);
ASSERT_EQ(ret->body_.named_expressions.size(), 1U);
auto *all = dynamic_cast<All *>(ret->body_.named_expressions[0]->expression_);
ASSERT_TRUE(all);
EXPECT_EQ(all->identifier_->name_, "x");
auto *list_literal = dynamic_cast<ListLiteral *>(all->list_expression_);
EXPECT_TRUE(list_literal);
auto *eq = dynamic_cast<EqualOperator *>(all->where_->expression_);
EXPECT_TRUE(eq);
}
}
TEST_P(CypherMainVisitorTest, ReturnSingle) {
{
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("RETURN single(x in [1,2,3])"), SyntaxException);
}
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN single(x IN [1,2,3] WHERE x = 2)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *ret = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(ret);
ASSERT_EQ(ret->body_.named_expressions.size(), 1U);
auto *single = dynamic_cast<Single *>(ret->body_.named_expressions[0]->expression_);
ASSERT_TRUE(single);
EXPECT_EQ(single->identifier_->name_, "x");
auto *list_literal = dynamic_cast<ListLiteral *>(single->list_expression_);
EXPECT_TRUE(list_literal);
auto *eq = dynamic_cast<EqualOperator *>(single->where_->expression_);
EXPECT_TRUE(eq);
}
TEST_P(CypherMainVisitorTest, ReturnReduce) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN reduce(sum = 0, x IN [1,2,3] | sum + x)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *ret = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(ret);
ASSERT_EQ(ret->body_.named_expressions.size(), 1U);
auto *reduce = dynamic_cast<Reduce *>(ret->body_.named_expressions[0]->expression_);
ASSERT_TRUE(reduce);
EXPECT_EQ(reduce->accumulator_->name_, "sum");
ast_generator.CheckLiteral(reduce->initializer_, 0);
EXPECT_EQ(reduce->identifier_->name_, "x");
auto *list_literal = dynamic_cast<ListLiteral *>(reduce->list_);
EXPECT_TRUE(list_literal);
auto *add = dynamic_cast<AdditionOperator *>(reduce->expression_);
EXPECT_TRUE(add);
}
TEST_P(CypherMainVisitorTest, ReturnExtract) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN extract(x IN [1,2,3] | sum + x)"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *ret = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(ret);
ASSERT_EQ(ret->body_.named_expressions.size(), 1U);
auto *extract = dynamic_cast<Extract *>(ret->body_.named_expressions[0]->expression_);
ASSERT_TRUE(extract);
EXPECT_EQ(extract->identifier_->name_, "x");
auto *list_literal = dynamic_cast<ListLiteral *>(extract->list_);
EXPECT_TRUE(list_literal);
auto *add = dynamic_cast<AdditionOperator *>(extract->expression_);
EXPECT_TRUE(add);
}
TEST_P(CypherMainVisitorTest, MatchBfsReturn) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("MATCH (n) -[r:type1|type2 *bfs..10 (e, n|e.prop = 42)]-> (m) RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
auto *bfs = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(bfs);
EXPECT_TRUE(bfs->IsVariable());
EXPECT_EQ(bfs->direction_, EdgeAtom::Direction::OUT);
EXPECT_THAT(bfs->edge_types_, UnorderedElementsAre(ast_generator.EdgeType("type1"), ast_generator.EdgeType("type2")));
EXPECT_EQ(bfs->identifier_->name_, "r");
EXPECT_EQ(bfs->filter_lambda_.inner_edge->name_, "e");
EXPECT_TRUE(bfs->filter_lambda_.inner_edge->user_declared_);
EXPECT_EQ(bfs->filter_lambda_.inner_node->name_, "n");
EXPECT_TRUE(bfs->filter_lambda_.inner_node->user_declared_);
ast_generator.CheckLiteral(bfs->upper_bound_, 10);
auto *eq = dynamic_cast<EqualOperator *>(bfs->filter_lambda_.expression);
ASSERT_TRUE(eq);
}
TEST_P(CypherMainVisitorTest, MatchVariableLambdaSymbols) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH () -[*]- () RETURN *"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
auto *var_expand = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(var_expand);
ASSERT_TRUE(var_expand->IsVariable());
EXPECT_FALSE(var_expand->filter_lambda_.inner_edge->user_declared_);
EXPECT_FALSE(var_expand->filter_lambda_.inner_node->user_declared_);
}
TEST_P(CypherMainVisitorTest, MatchWShortestReturn) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("MATCH ()-[r:type1|type2 *wShortest 10 (we, wn | 42) total_weight "
"(e, n | true)]->() RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
auto *shortest = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(shortest);
EXPECT_TRUE(shortest->IsVariable());
EXPECT_EQ(shortest->type_, EdgeAtom::Type::WEIGHTED_SHORTEST_PATH);
EXPECT_EQ(shortest->direction_, EdgeAtom::Direction::OUT);
EXPECT_THAT(shortest->edge_types_,
UnorderedElementsAre(ast_generator.EdgeType("type1"), ast_generator.EdgeType("type2")));
ast_generator.CheckLiteral(shortest->upper_bound_, 10);
EXPECT_FALSE(shortest->lower_bound_);
EXPECT_EQ(shortest->identifier_->name_, "r");
EXPECT_EQ(shortest->filter_lambda_.inner_edge->name_, "e");
EXPECT_TRUE(shortest->filter_lambda_.inner_edge->user_declared_);
EXPECT_EQ(shortest->filter_lambda_.inner_node->name_, "n");
EXPECT_TRUE(shortest->filter_lambda_.inner_node->user_declared_);
ast_generator.CheckLiteral(shortest->filter_lambda_.expression, true);
EXPECT_EQ(shortest->weight_lambda_.inner_edge->name_, "we");
EXPECT_TRUE(shortest->weight_lambda_.inner_edge->user_declared_);
EXPECT_EQ(shortest->weight_lambda_.inner_node->name_, "wn");
EXPECT_TRUE(shortest->weight_lambda_.inner_node->user_declared_);
ast_generator.CheckLiteral(shortest->weight_lambda_.expression, 42);
ASSERT_TRUE(shortest->total_weight_);
EXPECT_EQ(shortest->total_weight_->name_, "total_weight");
EXPECT_TRUE(shortest->total_weight_->user_declared_);
}
TEST_P(CypherMainVisitorTest, MatchWShortestNoFilterReturn) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH ()-[r:type1|type2 *wShortest 10 (we, wn | 42)]->() "
"RETURN r"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match);
ASSERT_EQ(match->patterns_.size(), 1U);
ASSERT_EQ(match->patterns_[0]->atoms_.size(), 3U);
auto *shortest = dynamic_cast<EdgeAtom *>(match->patterns_[0]->atoms_[1]);
ASSERT_TRUE(shortest);
EXPECT_TRUE(shortest->IsVariable());
EXPECT_EQ(shortest->type_, EdgeAtom::Type::WEIGHTED_SHORTEST_PATH);
EXPECT_EQ(shortest->direction_, EdgeAtom::Direction::OUT);
EXPECT_THAT(shortest->edge_types_,
UnorderedElementsAre(ast_generator.EdgeType("type1"), ast_generator.EdgeType("type2")));
ast_generator.CheckLiteral(shortest->upper_bound_, 10);
EXPECT_FALSE(shortest->lower_bound_);
EXPECT_EQ(shortest->identifier_->name_, "r");
EXPECT_FALSE(shortest->filter_lambda_.expression);
EXPECT_FALSE(shortest->filter_lambda_.inner_edge->user_declared_);
EXPECT_FALSE(shortest->filter_lambda_.inner_node->user_declared_);
EXPECT_EQ(shortest->weight_lambda_.inner_edge->name_, "we");
EXPECT_TRUE(shortest->weight_lambda_.inner_edge->user_declared_);
EXPECT_EQ(shortest->weight_lambda_.inner_node->name_, "wn");
EXPECT_TRUE(shortest->weight_lambda_.inner_node->user_declared_);
ast_generator.CheckLiteral(shortest->weight_lambda_.expression, 42);
ASSERT_TRUE(shortest->total_weight_);
EXPECT_FALSE(shortest->total_weight_->user_declared_);
}
TEST_P(CypherMainVisitorTest, SemanticExceptionOnWShortestLowerBound) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("MATCH ()-[r *wShortest 10.. (e, n | 42)]-() RETURN r"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("MATCH ()-[r *wShortest 10..20 (e, n | 42)]-() RETURN r"), SemanticException);
}
TEST_P(CypherMainVisitorTest, SemanticExceptionOnWShortestWithoutLambda) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("MATCH ()-[r *wShortest]-() RETURN r"), SemanticException);
}
TEST_P(CypherMainVisitorTest, SemanticExceptionOnUnionTypeMix) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN 5 as X UNION ALL RETURN 6 AS X UNION RETURN 7 AS X"),
SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 5 as X UNION RETURN 6 AS X UNION ALL RETURN 7 AS X"),
SemanticException);
}
TEST_P(CypherMainVisitorTest, Union) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN 5 AS X, 6 AS Y UNION RETURN 6 AS X, 5 AS Y"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.order_by.size(), 0U);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 2U);
ASSERT_FALSE(return_clause->body_.limit);
ASSERT_FALSE(return_clause->body_.skip);
ASSERT_FALSE(return_clause->body_.distinct);
ASSERT_EQ(query->cypher_unions_.size(), 1);
auto *cypher_union = query->cypher_unions_.at(0);
ASSERT_TRUE(cypher_union);
ASSERT_TRUE(cypher_union->distinct_);
ASSERT_TRUE(single_query = cypher_union->single_query_);
ASSERT_EQ(single_query->clauses_.size(), 1U);
return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.order_by.size(), 0U);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 2U);
ASSERT_FALSE(return_clause->body_.limit);
ASSERT_FALSE(return_clause->body_.skip);
ASSERT_FALSE(return_clause->body_.distinct);
}
TEST_P(CypherMainVisitorTest, UnionAll) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("RETURN 5 AS X UNION ALL RETURN 6 AS X UNION ALL RETURN 7 AS X"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.order_by.size(), 0U);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1U);
ASSERT_FALSE(return_clause->body_.limit);
ASSERT_FALSE(return_clause->body_.skip);
ASSERT_FALSE(return_clause->body_.distinct);
ASSERT_EQ(query->cypher_unions_.size(), 2);
auto *cypher_union = query->cypher_unions_.at(0);
ASSERT_TRUE(cypher_union);
ASSERT_FALSE(cypher_union->distinct_);
ASSERT_TRUE(single_query = cypher_union->single_query_);
ASSERT_EQ(single_query->clauses_.size(), 1U);
return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.order_by.size(), 0U);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1U);
ASSERT_FALSE(return_clause->body_.limit);
ASSERT_FALSE(return_clause->body_.skip);
ASSERT_FALSE(return_clause->body_.distinct);
cypher_union = query->cypher_unions_.at(1);
ASSERT_TRUE(cypher_union);
ASSERT_FALSE(cypher_union->distinct_);
ASSERT_TRUE(single_query = cypher_union->single_query_);
ASSERT_EQ(single_query->clauses_.size(), 1U);
return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_FALSE(return_clause->body_.all_identifiers);
ASSERT_EQ(return_clause->body_.order_by.size(), 0U);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1U);
ASSERT_FALSE(return_clause->body_.limit);
ASSERT_FALSE(return_clause->body_.skip);
ASSERT_FALSE(return_clause->body_.distinct);
}
void check_auth_query(
Base *ast_generator, std::string input, AuthQuery::Action action, std::string user, std::string role,
std::string user_or_role, std::optional<TypedValue> password, std::vector<AuthQuery::Privilege> privileges,
std::vector<std::unordered_map<AuthQuery::FineGrainedPrivilege, std::vector<std::string>>> label_privileges,
std::vector<std::unordered_map<AuthQuery::FineGrainedPrivilege, std::vector<std::string>>> edge_type_privileges) {
auto *auth_query = dynamic_cast<AuthQuery *>(ast_generator->ParseQuery(input));
ASSERT_TRUE(auth_query);
EXPECT_EQ(auth_query->action_, action);
EXPECT_EQ(auth_query->user_, user);
EXPECT_EQ(auth_query->role_, role);
EXPECT_EQ(auth_query->user_or_role_, user_or_role);
ASSERT_EQ(static_cast<bool>(auth_query->password_), static_cast<bool>(password));
if (password) {
ast_generator->CheckLiteral(auth_query->password_, *password);
}
EXPECT_EQ(auth_query->privileges_, privileges);
EXPECT_EQ(auth_query->label_privileges_, label_privileges);
EXPECT_EQ(auth_query->edge_type_privileges_, edge_type_privileges);
}
TEST_P(CypherMainVisitorTest, UserOrRoleName) {
auto &ast_generator = *GetParam();
check_auth_query(&ast_generator, "CREATE ROLE `user`", AuthQuery::Action::CREATE_ROLE, "", "user", "", {}, {}, {},
{});
check_auth_query(&ast_generator, "CREATE ROLE us___er", AuthQuery::Action::CREATE_ROLE, "", "us___er", "", {}, {}, {},
{});
check_auth_query(&ast_generator, "CREATE ROLE `us+er`", AuthQuery::Action::CREATE_ROLE, "", "us+er", "", {}, {}, {},
{});
check_auth_query(&ast_generator, "CREATE ROLE `us|er`", AuthQuery::Action::CREATE_ROLE, "", "us|er", "", {}, {}, {},
{});
check_auth_query(&ast_generator, "CREATE ROLE `us er`", AuthQuery::Action::CREATE_ROLE, "", "us er", "", {}, {}, {},
{});
}
TEST_P(CypherMainVisitorTest, CreateRole) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("CREATE ROLE"), SyntaxException);
check_auth_query(&ast_generator, "CREATE ROLE rola", AuthQuery::Action::CREATE_ROLE, "", "rola", "", {}, {}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("CREATE ROLE lagano rolamo"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, DropRole) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("DROP ROLE"), SyntaxException);
check_auth_query(&ast_generator, "DROP ROLE rola", AuthQuery::Action::DROP_ROLE, "", "rola", "", {}, {}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("DROP ROLE lagano rolamo"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, ShowRoles) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SHOW ROLES ROLES"), SyntaxException);
check_auth_query(&ast_generator, "SHOW ROLES", AuthQuery::Action::SHOW_ROLES, "", "", "", {}, {}, {}, {});
}
TEST_P(CypherMainVisitorTest, CreateUser) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("CREATE USER"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CREATE USER 123"), SyntaxException);
check_auth_query(&ast_generator, "CREATE USER user", AuthQuery::Action::CREATE_USER, "user", "", "", {}, {}, {}, {});
check_auth_query(&ast_generator, "CREATE USER user IDENTIFIED BY 'password'", AuthQuery::Action::CREATE_USER, "user",
"", "", TypedValue("password"), {}, {}, {});
check_auth_query(&ast_generator, "CREATE USER user IDENTIFIED BY ''", AuthQuery::Action::CREATE_USER, "user", "", "",
TypedValue(""), {}, {}, {});
check_auth_query(&ast_generator, "CREATE USER user IDENTIFIED BY null", AuthQuery::Action::CREATE_USER, "user", "",
"", TypedValue(), {}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("CRATE USER user IDENTIFIED BY password"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CREATE USER user IDENTIFIED BY 5"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CREATE USER user IDENTIFIED BY "), SyntaxException);
}
TEST_P(CypherMainVisitorTest, SetPassword) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SET PASSWORD FOR"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("SET PASSWORD FOR user "), SyntaxException);
check_auth_query(&ast_generator, "SET PASSWORD FOR user TO null", AuthQuery::Action::SET_PASSWORD, "user", "", "",
TypedValue(), {}, {}, {});
check_auth_query(&ast_generator, "SET PASSWORD FOR user TO 'password'", AuthQuery::Action::SET_PASSWORD, "user", "",
"", TypedValue("password"), {}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("SET PASSWORD FOR user To 5"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, DropUser) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("DROP USER"), SyntaxException);
check_auth_query(&ast_generator, "DROP USER user", AuthQuery::Action::DROP_USER, "user", "", "", {}, {}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("DROP USER lagano rolamo"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, ShowUsers) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SHOW USERS ROLES"), SyntaxException);
check_auth_query(&ast_generator, "SHOW USERS", AuthQuery::Action::SHOW_USERS, "", "", "", {}, {}, {}, {});
}
TEST_P(CypherMainVisitorTest, SetRole) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SET ROLE"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("SET ROLE user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("SET ROLE FOR user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("SET ROLE FOR user TO"), SyntaxException);
check_auth_query(&ast_generator, "SET ROLE FOR user TO role", AuthQuery::Action::SET_ROLE, "user", "role", "", {}, {},
{}, {});
check_auth_query(&ast_generator, "SET ROLE FOR user TO null", AuthQuery::Action::SET_ROLE, "user", "null", "", {}, {},
{}, {});
}
TEST_P(CypherMainVisitorTest, ClearRole) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("CLEAR ROLE"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CLEAR ROLE user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CLEAR ROLE FOR user TO"), SyntaxException);
check_auth_query(&ast_generator, "CLEAR ROLE FOR user", AuthQuery::Action::CLEAR_ROLE, "user", "", "", {}, {}, {},
{});
}
TEST_P(CypherMainVisitorTest, GrantPrivilege) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("GRANT"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("GRANT TO user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("GRANT BLABLA TO user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("GRANT MATCH, TO user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("GRANT MATCH, BLABLA TO user"), SyntaxException);
check_auth_query(&ast_generator, "GRANT MATCH TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MATCH}, {}, {});
check_auth_query(&ast_generator, "GRANT MATCH, AUTH TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MATCH, AuthQuery::Privilege::AUTH}, {}, {});
// Verify that all privileges are correctly visited.
check_auth_query(&ast_generator, "GRANT CREATE TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::CREATE}, {}, {});
check_auth_query(&ast_generator, "GRANT DELETE TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DELETE}, {}, {});
check_auth_query(&ast_generator, "GRANT MERGE TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MERGE}, {}, {});
check_auth_query(&ast_generator, "GRANT SET TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::SET}, {}, {});
check_auth_query(&ast_generator, "GRANT REMOVE TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::REMOVE}, {}, {});
check_auth_query(&ast_generator, "GRANT INDEX TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::INDEX}, {}, {});
check_auth_query(&ast_generator, "GRANT STATS TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::STATS}, {}, {});
check_auth_query(&ast_generator, "GRANT AUTH TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::AUTH}, {}, {});
check_auth_query(&ast_generator, "GRANT CONSTRAINT TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::CONSTRAINT}, {}, {});
check_auth_query(&ast_generator, "GRANT DUMP TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DUMP}, {}, {});
check_auth_query(&ast_generator, "GRANT REPLICATION TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::REPLICATION}, {}, {});
check_auth_query(&ast_generator, "GRANT DURABILITY TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DURABILITY}, {}, {});
check_auth_query(&ast_generator, "GRANT READ_FILE TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::READ_FILE}, {}, {});
check_auth_query(&ast_generator, "GRANT FREE_MEMORY TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::FREE_MEMORY}, {}, {});
check_auth_query(&ast_generator, "GRANT TRIGGER TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::TRIGGER}, {}, {});
check_auth_query(&ast_generator, "GRANT CONFIG TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::CONFIG}, {}, {});
check_auth_query(&ast_generator, "GRANT STREAM TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::STREAM}, {}, {});
check_auth_query(&ast_generator, "GRANT WEBSOCKET TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::WEBSOCKET}, {}, {});
check_auth_query(&ast_generator, "GRANT MODULE_READ TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MODULE_READ}, {}, {});
check_auth_query(&ast_generator, "GRANT MODULE_WRITE TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MODULE_WRITE}, {}, {});
std::vector<std::unordered_map<AuthQuery::FineGrainedPrivilege, std::vector<std::string>>> label_privileges{};
std::vector<std::unordered_map<AuthQuery::FineGrainedPrivilege, std::vector<std::string>>> edge_type_privileges{};
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::READ}, {{"*"}}}});
check_auth_query(&ast_generator, "GRANT READ ON LABELS * TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user",
{}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::UPDATE}, {{"*"}}}});
check_auth_query(&ast_generator, "GRANT UPDATE ON LABELS * TO user", AuthQuery::Action::GRANT_PRIVILEGE, "", "",
"user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::CREATE_DELETE}, {{"*"}}}});
check_auth_query(&ast_generator, "GRANT CREATE_DELETE ON LABELS * TO user", AuthQuery::Action::GRANT_PRIVILEGE, "",
"", "user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::READ}, {{"Label1"}, {"Label2"}}}});
check_auth_query(&ast_generator, "GRANT READ ON LABELS :Label1, :Label2 TO user", AuthQuery::Action::GRANT_PRIVILEGE,
"", "", "user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::UPDATE}, {{"Label1"}, {"Label2"}}}});
check_auth_query(&ast_generator, "GRANT UPDATE ON LABELS :Label1, :Label2 TO user",
AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::CREATE_DELETE}, {{"Label1"}, {"Label2"}}}});
check_auth_query(&ast_generator, "GRANT CREATE_DELETE ON LABELS :Label1, :Label2 TO user",
AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::READ}, {{"Label1"}, {"Label2"}}},
{{AuthQuery::FineGrainedPrivilege::UPDATE}, {{"Label3"}}}});
check_auth_query(&ast_generator, "GRANT READ ON LABELS :Label1, :Label2, UPDATE ON LABELS :Label3 TO user",
AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::READ}, {{"Label1"}, {"Label2"}}}});
edge_type_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::READ}, {{"Edge1"}, {"Edge2"}, {"Edge3"}}}});
check_auth_query(&ast_generator,
"GRANT READ ON LABELS :Label1, :Label2, READ ON EDGE_TYPES :Edge1, :Edge2, :Edge3 TO user",
AuthQuery::Action::GRANT_PRIVILEGE, "", "", "user", {}, {}, label_privileges, edge_type_privileges);
label_privileges.clear();
edge_type_privileges.clear();
}
TEST_P(CypherMainVisitorTest, DenyPrivilege) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("DENY"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("DENY TO user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("DENY BLABLA TO user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("DENY MATCH, TO user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("DENY MATCH, BLABLA TO user"), SyntaxException);
check_auth_query(&ast_generator, "DENY MATCH TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MATCH}, {}, {});
check_auth_query(&ast_generator, "DENY MATCH, AUTH TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MATCH, AuthQuery::Privilege::AUTH}, {}, {});
// Verify that all privileges are correctly visited.
check_auth_query(&ast_generator, "DENY CREATE TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::CREATE}, {}, {});
check_auth_query(&ast_generator, "DENY DELETE TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DELETE}, {}, {});
check_auth_query(&ast_generator, "DENY MERGE TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MERGE}, {}, {});
check_auth_query(&ast_generator, "DENY SET TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::SET}, {}, {});
check_auth_query(&ast_generator, "DENY REMOVE TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::REMOVE}, {}, {});
check_auth_query(&ast_generator, "DENY INDEX TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::INDEX}, {}, {});
check_auth_query(&ast_generator, "DENY STATS TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::STATS}, {}, {});
check_auth_query(&ast_generator, "DENY AUTH TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::AUTH}, {}, {});
check_auth_query(&ast_generator, "DENY CONSTRAINT TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::CONSTRAINT}, {}, {});
check_auth_query(&ast_generator, "DENY DUMP TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DUMP}, {}, {});
check_auth_query(&ast_generator, "DENY WEBSOCKET TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::WEBSOCKET}, {}, {});
check_auth_query(&ast_generator, "DENY MODULE_READ TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MODULE_READ}, {}, {});
check_auth_query(&ast_generator, "DENY MODULE_WRITE TO user", AuthQuery::Action::DENY_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MODULE_WRITE}, {}, {});
}
TEST_P(CypherMainVisitorTest, RevokePrivilege) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("REVOKE"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("REVOKE FROM user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("REVOKE BLABLA FROM user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("REVOKE MATCH, FROM user"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("REVOKE MATCH, BLABLA FROM user"), SyntaxException);
check_auth_query(&ast_generator, "REVOKE MATCH FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MATCH}, {}, {});
check_auth_query(&ast_generator, "REVOKE MATCH, AUTH FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user",
{}, {AuthQuery::Privilege::MATCH, AuthQuery::Privilege::AUTH}, {}, {});
check_auth_query(&ast_generator, "REVOKE ALL PRIVILEGES FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "",
"user", {}, kPrivilegesAll, {}, {});
// Verify that all privileges are correctly visited.
check_auth_query(&ast_generator, "REVOKE CREATE FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::CREATE}, {}, {});
check_auth_query(&ast_generator, "REVOKE DELETE FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DELETE}, {}, {});
check_auth_query(&ast_generator, "REVOKE MERGE FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::MERGE}, {}, {});
check_auth_query(&ast_generator, "REVOKE SET FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::SET}, {}, {});
check_auth_query(&ast_generator, "REVOKE REMOVE FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::REMOVE}, {}, {});
check_auth_query(&ast_generator, "REVOKE INDEX FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::INDEX}, {}, {});
check_auth_query(&ast_generator, "REVOKE STATS FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::STATS}, {}, {});
check_auth_query(&ast_generator, "REVOKE AUTH FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::AUTH}, {}, {});
check_auth_query(&ast_generator, "REVOKE CONSTRAINT FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user",
{}, {AuthQuery::Privilege::CONSTRAINT}, {}, {});
check_auth_query(&ast_generator, "REVOKE DUMP FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{AuthQuery::Privilege::DUMP}, {}, {});
check_auth_query(&ast_generator, "REVOKE WEBSOCKET FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user",
{}, {AuthQuery::Privilege::WEBSOCKET}, {}, {});
check_auth_query(&ast_generator, "REVOKE MODULE_READ FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user",
{}, {AuthQuery::Privilege::MODULE_READ}, {}, {});
check_auth_query(&ast_generator, "REVOKE MODULE_WRITE FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user",
{}, {AuthQuery::Privilege::MODULE_WRITE}, {}, {});
std::vector<std::unordered_map<AuthQuery::FineGrainedPrivilege, std::vector<std::string>>> label_privileges{};
std::vector<std::unordered_map<AuthQuery::FineGrainedPrivilege, std::vector<std::string>>> edge_type_privileges{};
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::CREATE_DELETE}, {{"*"}}}});
check_auth_query(&ast_generator, "REVOKE LABELS * FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {},
{}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::CREATE_DELETE}, {{"Label1"}, {"Label2"}}}});
check_auth_query(&ast_generator, "REVOKE LABELS :Label1, :Label2 FROM user", AuthQuery::Action::REVOKE_PRIVILEGE, "",
"", "user", {}, {}, label_privileges, {});
label_privileges.clear();
label_privileges.push_back({{{AuthQuery::FineGrainedPrivilege::CREATE_DELETE}, {{"Label1"}, {"Label2"}}}});
edge_type_privileges.push_back(
{{{AuthQuery::FineGrainedPrivilege::CREATE_DELETE}, {{"Edge1"}, {"Edge2"}, {"Edge3"}}}});
check_auth_query(&ast_generator, "REVOKE LABELS :Label1, :Label2, EDGE_TYPES :Edge1, :Edge2, :Edge3 FROM user",
AuthQuery::Action::REVOKE_PRIVILEGE, "", "", "user", {}, {}, label_privileges, edge_type_privileges);
label_privileges.clear();
edge_type_privileges.clear();
}
TEST_P(CypherMainVisitorTest, ShowPrivileges) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SHOW PRIVILEGES FOR"), SyntaxException);
check_auth_query(&ast_generator, "SHOW PRIVILEGES FOR user", AuthQuery::Action::SHOW_PRIVILEGES, "", "", "user", {},
{}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("SHOW PRIVILEGES FOR user1, user2"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, ShowRoleForUser) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SHOW ROLE FOR "), SyntaxException);
check_auth_query(&ast_generator, "SHOW ROLE FOR user", AuthQuery::Action::SHOW_ROLE_FOR_USER, "user", "", "", {}, {},
{}, {});
ASSERT_THROW(ast_generator.ParseQuery("SHOW ROLE FOR user1, user2"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, ShowUsersForRole) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("SHOW USERS FOR "), SyntaxException);
check_auth_query(&ast_generator, "SHOW USERS FOR role", AuthQuery::Action::SHOW_USERS_FOR_ROLE, "", "role", "", {},
{}, {}, {});
ASSERT_THROW(ast_generator.ParseQuery("SHOW USERS FOR role1, role2"), SyntaxException);
}
void check_replication_query(Base *ast_generator, const ReplicationQuery *query, const std::string name,
const std::optional<TypedValue> socket_address, const ReplicationQuery::SyncMode sync_mode,
const std::optional<TypedValue> port = {}) {
EXPECT_EQ(query->replica_name_, name);
EXPECT_EQ(query->sync_mode_, sync_mode);
ASSERT_EQ(static_cast<bool>(query->socket_address_), static_cast<bool>(socket_address));
if (socket_address) {
ast_generator->CheckLiteral(query->socket_address_, *socket_address);
}
ASSERT_EQ(static_cast<bool>(query->port_), static_cast<bool>(port));
if (port) {
ast_generator->CheckLiteral(query->port_, *port);
}
}
TEST_P(CypherMainVisitorTest, TestShowReplicationMode) {
auto &ast_generator = *GetParam();
const std::string raw_query = "SHOW REPLICATION ROLE";
auto *parsed_query = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(raw_query));
EXPECT_EQ(parsed_query->action_, ReplicationQuery::Action::SHOW_REPLICATION_ROLE);
}
TEST_P(CypherMainVisitorTest, TestShowReplicasQuery) {
auto &ast_generator = *GetParam();
const std::string raw_query = "SHOW REPLICAS";
auto *parsed_query = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(raw_query));
EXPECT_EQ(parsed_query->action_, ReplicationQuery::Action::SHOW_REPLICAS);
}
TEST_P(CypherMainVisitorTest, TestSetReplicationMode) {
auto &ast_generator = *GetParam();
{
const std::string query = "SET REPLICATION ROLE";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = "SET REPLICATION ROLE TO BUTTERY";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = "SET REPLICATION ROLE TO MAIN";
auto *parsed_query = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(query));
EXPECT_EQ(parsed_query->action_, ReplicationQuery::Action::SET_REPLICATION_ROLE);
EXPECT_EQ(parsed_query->role_, ReplicationQuery::ReplicationRole::MAIN);
}
{
const std::string query = "SET REPLICATION ROLE TO MAIN WITH PORT 10000";
ASSERT_THROW(ast_generator.ParseQuery(query), SemanticException);
}
{
const std::string query = "SET REPLICATION ROLE TO REPLICA WITH PORT 10000";
auto *parsed_query = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(query));
EXPECT_EQ(parsed_query->action_, ReplicationQuery::Action::SET_REPLICATION_ROLE);
EXPECT_EQ(parsed_query->role_, ReplicationQuery::ReplicationRole::REPLICA);
ast_generator.CheckLiteral(parsed_query->port_, TypedValue(10000));
}
}
TEST_P(CypherMainVisitorTest, TestRegisterReplicationQuery) {
auto &ast_generator = *GetParam();
const std::string faulty_query = "REGISTER REPLICA TO";
ASSERT_THROW(ast_generator.ParseQuery(faulty_query), SyntaxException);
const std::string faulty_query_with_timeout = R"(REGISTER REPLICA replica1 SYNC WITH TIMEOUT 1.0 TO "127.0.0.1")";
ASSERT_THROW(ast_generator.ParseQuery(faulty_query_with_timeout), SyntaxException);
const std::string correct_query = R"(REGISTER REPLICA replica1 SYNC TO "127.0.0.1")";
auto *correct_query_parsed = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(correct_query));
check_replication_query(&ast_generator, correct_query_parsed, "replica1", TypedValue("127.0.0.1"),
ReplicationQuery::SyncMode::SYNC);
std::string full_query = R"(REGISTER REPLICA replica2 SYNC TO "1.1.1.1:10000")";
auto *full_query_parsed = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(full_query));
ASSERT_TRUE(full_query_parsed);
check_replication_query(&ast_generator, full_query_parsed, "replica2", TypedValue("1.1.1.1:10000"),
ReplicationQuery::SyncMode::SYNC);
}
TEST_P(CypherMainVisitorTest, TestDeleteReplica) {
auto &ast_generator = *GetParam();
std::string missing_name_query = "DROP REPLICA";
ASSERT_THROW(ast_generator.ParseQuery(missing_name_query), SyntaxException);
std::string correct_query = "DROP REPLICA replica1";
auto *correct_query_parsed = dynamic_cast<ReplicationQuery *>(ast_generator.ParseQuery(correct_query));
ASSERT_TRUE(correct_query_parsed);
EXPECT_EQ(correct_query_parsed->replica_name_, "replica1");
}
TEST_P(CypherMainVisitorTest, TestExplainRegularQuery) {
auto &ast_generator = *GetParam();
EXPECT_TRUE(dynamic_cast<ExplainQuery *>(ast_generator.ParseQuery("EXPLAIN RETURN n")));
}
TEST_P(CypherMainVisitorTest, TestExplainExplainQuery) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("EXPLAIN EXPLAIN RETURN n"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, TestExplainAuthQuery) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("EXPLAIN SHOW ROLES"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, TestProfileRegularQuery) {
{
auto &ast_generator = *GetParam();
EXPECT_TRUE(dynamic_cast<ProfileQuery *>(ast_generator.ParseQuery("PROFILE RETURN n")));
}
}
TEST_P(CypherMainVisitorTest, TestProfileComplicatedQuery) {
{
auto &ast_generator = *GetParam();
EXPECT_TRUE(
dynamic_cast<ProfileQuery *>(ast_generator.ParseQuery("profile optional match (n) where n.hello = 5 "
"return n union optional match (n) where n.there = 10 "
"return n")));
}
}
TEST_P(CypherMainVisitorTest, TestProfileProfileQuery) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("PROFILE PROFILE RETURN n"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, TestProfileAuthQuery) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("PROFILE SHOW ROLES"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, TestShowStorageInfo) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<SystemInfoQuery *>(ast_generator.ParseQuery("SHOW STORAGE INFO"));
ASSERT_TRUE(query);
EXPECT_EQ(query->info_type_, SystemInfoQuery::InfoType::STORAGE);
}
TEST_P(CypherMainVisitorTest, TestShowIndexInfo) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<DatabaseInfoQuery *>(ast_generator.ParseQuery("SHOW INDEX INFO"));
ASSERT_TRUE(query);
EXPECT_EQ(query->info_type_, DatabaseInfoQuery::InfoType::INDEX);
}
TEST_P(CypherMainVisitorTest, TestShowConstraintInfo) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<DatabaseInfoQuery *>(ast_generator.ParseQuery("SHOW CONSTRAINT INFO"));
ASSERT_TRUE(query);
EXPECT_EQ(query->info_type_, DatabaseInfoQuery::InfoType::CONSTRAINT);
}
TEST_P(CypherMainVisitorTest, CreateConstraintSyntaxError) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (:label) ASSERT EXISTS"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT () ASSERT EXISTS"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON () ASSERT EXISTS(prop1)"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON () ASSERT EXISTS (prop1, prop2)"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"EXISTS (n.prop1, missing.prop2)"),
SemanticException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"EXISTS (m.prop1, m.prop2)"),
SemanticException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (:label) ASSERT IS UNIQUE"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT () ASSERT IS UNIQUE"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON () ASSERT prop1 IS UNIQUE"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON () ASSERT prop1, prop2 IS UNIQUE"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"n.prop1, missing.prop2 IS UNIQUE"),
SemanticException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"m.prop1, m.prop2 IS UNIQUE"),
SemanticException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (:label) ASSERT IS NODE KEY"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT () ASSERT IS NODE KEY"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON () ASSERT (prop1) IS NODE KEY"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON () ASSERT (prop1, prop2) IS NODE KEY"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"(n.prop1, missing.prop2) IS NODE KEY"),
SemanticException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"(m.prop1, m.prop2) IS NODE KEY"),
SemanticException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"n.prop1, n.prop2 IS NODE KEY"),
SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"exists(n.prop1, n.prop2) IS NODE KEY"),
SyntaxException);
}
TEST_P(CypherMainVisitorTest, CreateConstraint) {
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT EXISTS(n.prop1)"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::CREATE);
EXPECT_EQ(query->constraint_.type, Constraint::Type::EXISTS);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties, UnorderedElementsAre(ast_generator.Prop("prop1")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT EXISTS (n.prop1, n.prop2)"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::CREATE);
EXPECT_EQ(query->constraint_.type, Constraint::Type::EXISTS);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties,
UnorderedElementsAre(ast_generator.Prop("prop1"), ast_generator.Prop("prop2")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT n.prop1 IS UNIQUE"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::CREATE);
EXPECT_EQ(query->constraint_.type, Constraint::Type::UNIQUE);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties, UnorderedElementsAre(ast_generator.Prop("prop1")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT n.prop1, n.prop2 IS UNIQUE"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::CREATE);
EXPECT_EQ(query->constraint_.type, Constraint::Type::UNIQUE);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties,
UnorderedElementsAre(ast_generator.Prop("prop1"), ast_generator.Prop("prop2")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT (n.prop1) IS NODE KEY"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::CREATE);
EXPECT_EQ(query->constraint_.type, Constraint::Type::NODE_KEY);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties, UnorderedElementsAre(ast_generator.Prop("prop1")));
}
{
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<ConstraintQuery *>(ast_generator.ParseQuery("CREATE CONSTRAINT ON (n:label) ASSERT "
"(n.prop1, n.prop2) IS NODE KEY"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::CREATE);
EXPECT_EQ(query->constraint_.type, Constraint::Type::NODE_KEY);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties,
UnorderedElementsAre(ast_generator.Prop("prop1"), ast_generator.Prop("prop2")));
}
}
TEST_P(CypherMainVisitorTest, DropConstraint) {
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("DROP CONSTRAINT ON (n:label) ASSERT EXISTS(n.prop1)"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::DROP);
EXPECT_EQ(query->constraint_.type, Constraint::Type::EXISTS);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties, UnorderedElementsAre(ast_generator.Prop("prop1")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("DROP CONSTRAINT ON (n:label) ASSERT EXISTS(n.prop1, n.prop2)"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::DROP);
EXPECT_EQ(query->constraint_.type, Constraint::Type::EXISTS);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties,
UnorderedElementsAre(ast_generator.Prop("prop1"), ast_generator.Prop("prop2")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("DROP CONSTRAINT ON (n:label) ASSERT n.prop1 IS UNIQUE"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::DROP);
EXPECT_EQ(query->constraint_.type, Constraint::Type::UNIQUE);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties, UnorderedElementsAre(ast_generator.Prop("prop1")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("DROP CONSTRAINT ON (n:label) ASSERT n.prop1, n.prop2 IS UNIQUE"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::DROP);
EXPECT_EQ(query->constraint_.type, Constraint::Type::UNIQUE);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties,
UnorderedElementsAre(ast_generator.Prop("prop1"), ast_generator.Prop("prop2")));
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<ConstraintQuery *>(
ast_generator.ParseQuery("DROP CONSTRAINT ON (n:label) ASSERT (n.prop1) IS NODE KEY"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::DROP);
EXPECT_EQ(query->constraint_.type, Constraint::Type::NODE_KEY);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties, UnorderedElementsAre(ast_generator.Prop("prop1")));
}
{
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<ConstraintQuery *>(ast_generator.ParseQuery("DROP CONSTRAINT ON (n:label) ASSERT "
"(n.prop1, n.prop2) IS NODE KEY"));
ASSERT_TRUE(query);
EXPECT_EQ(query->action_type_, ConstraintQuery::ActionType::DROP);
EXPECT_EQ(query->constraint_.type, Constraint::Type::NODE_KEY);
EXPECT_EQ(query->constraint_.label, ast_generator.Label("label"));
EXPECT_THAT(query->constraint_.properties,
UnorderedElementsAre(ast_generator.Prop("prop1"), ast_generator.Prop("prop2")));
}
}
TEST_P(CypherMainVisitorTest, RegexMatch) {
{
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (n) WHERE n.name =~ \".*bla.*\" RETURN n.name"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *match_clause = dynamic_cast<Match *>(single_query->clauses_[0]);
ASSERT_TRUE(match_clause);
auto *regex_match = dynamic_cast<RegexMatch *>(match_clause->where_->expression_);
ASSERT_TRUE(regex_match);
ASSERT_TRUE(dynamic_cast<PropertyLookup *>(regex_match->string_expr_));
ast_generator.CheckLiteral(regex_match->regex_, ".*bla.*");
}
{
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN \"text\" =~ \".*bla.*\""));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *return_clause = dynamic_cast<Return *>(single_query->clauses_[0]);
ASSERT_TRUE(return_clause);
ASSERT_EQ(return_clause->body_.named_expressions.size(), 1U);
auto *named_expression = return_clause->body_.named_expressions[0];
auto *regex_match = dynamic_cast<RegexMatch *>(named_expression->expression_);
ASSERT_TRUE(regex_match);
ast_generator.CheckLiteral(regex_match->string_expr_, "text");
ast_generator.CheckLiteral(regex_match->regex_, ".*bla.*");
}
}
// NOLINTNEXTLINE(hicpp-special-member-functions)
TEST_P(CypherMainVisitorTest, DumpDatabase) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<DumpQuery *>(ast_generator.ParseQuery("DUMP DATABASE"));
ASSERT_TRUE(query);
}
namespace {
template <class TAst>
void CheckCallProcedureDefaultMemoryLimit(const TAst &ast, const CallProcedure &call_proc) {
// Should be 100 MB
auto *literal = dynamic_cast<PrimitiveLiteral *>(call_proc.memory_limit_);
ASSERT_TRUE(literal);
TypedValue value(literal->value_);
ASSERT_TRUE(TypedValue::BoolEqual{}(value, TypedValue(100)));
ASSERT_EQ(call_proc.memory_scale_, 1024 * 1024);
}
} // namespace
TEST_P(CypherMainVisitorTest, CallProcedureWithDotsInName) {
AddProc(*mock_module_with_dots_in_name, "proc", {}, {"res"}, ProcedureType::WRITE);
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mock_module.with.dots.in.name.proc() YIELD res"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mock_module.with.dots.in.name.proc");
ASSERT_TRUE(call_proc->arguments_.empty());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> expected_names{"res"};
ASSERT_EQ(identifier_names, expected_names);
ASSERT_EQ(identifier_names, call_proc->result_fields_);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithDashesInName) {
AddProc(*mock_module, "proc-with-dashes", {}, {"res"}, ProcedureType::READ);
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL `mock_module.proc-with-dashes`() YIELD res"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mock_module.proc-with-dashes");
ASSERT_TRUE(call_proc->arguments_.empty());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> expected_names{"res"};
ASSERT_EQ(identifier_names, expected_names);
ASSERT_EQ(identifier_names, call_proc->result_fields_);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithYieldSomeFields) {
auto &ast_generator = *GetParam();
auto check_proc = [this, &ast_generator](const ProcedureType type) {
const auto proc_name = std::string{"proc_"} + ToString(type);
SCOPED_TRACE(proc_name);
const auto fully_qualified_proc_name = std::string{"mock_module."} + proc_name;
AddProc(*mock_module, proc_name.c_str(), {}, {"fst", "field-with-dashes", "last_field"}, type);
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(
fmt::format("CALL {}() YIELD fst, `field-with-dashes`, last_field", fully_qualified_proc_name)));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->is_write_, type == ProcedureType::WRITE);
ASSERT_EQ(call_proc->procedure_name_, fully_qualified_proc_name);
ASSERT_TRUE(call_proc->arguments_.empty());
ASSERT_EQ(call_proc->result_fields_.size(), 3U);
ASSERT_EQ(call_proc->result_identifiers_.size(), call_proc->result_fields_.size());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> expected_names{"fst", "field-with-dashes", "last_field"};
ASSERT_EQ(identifier_names, expected_names);
ASSERT_EQ(identifier_names, call_proc->result_fields_);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
};
check_proc(ProcedureType::READ);
check_proc(ProcedureType::WRITE);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithYieldAliasedFields) {
AddProc(*mock_module, "proc", {}, {"fst", "snd", "thrd"}, ProcedureType::READ);
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mock_module.proc() YIELD fst AS res1, snd AS "
"`result-with-dashes`, thrd AS last_result"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mock_module.proc");
ASSERT_TRUE(call_proc->arguments_.empty());
ASSERT_EQ(call_proc->result_fields_.size(), 3U);
ASSERT_EQ(call_proc->result_identifiers_.size(), call_proc->result_fields_.size());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> aliased_names{"res1", "result-with-dashes", "last_result"};
ASSERT_EQ(identifier_names, aliased_names);
std::vector<std::string> field_names{"fst", "snd", "thrd"};
ASSERT_EQ(call_proc->result_fields_, field_names);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithArguments) {
AddProc(*mock_module, "proc", {"arg1", "arg2", "arg3"}, {"res"}, ProcedureType::READ);
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mock_module.proc(0, 1, 2) YIELD res"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mock_module.proc");
ASSERT_EQ(call_proc->arguments_.size(), 3U);
for (int64_t i = 0; i < 3; ++i) {
ast_generator.CheckLiteral(call_proc->arguments_[i], i);
}
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> expected_names{"res"};
ASSERT_EQ(identifier_names, expected_names);
ASSERT_EQ(identifier_names, call_proc->result_fields_);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureYieldAsterisk) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.procedures() YIELD *"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.procedures");
ASSERT_TRUE(call_proc->arguments_.empty());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
ASSERT_THAT(identifier_names, UnorderedElementsAre("name", "signature", "is_write", "path", "is_editable"));
ASSERT_EQ(identifier_names, call_proc->result_fields_);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureYieldAsteriskReturnAsterisk) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.procedures() YIELD * RETURN *"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *ret = dynamic_cast<Return *>(single_query->clauses_[1]);
ASSERT_TRUE(ret);
ASSERT_TRUE(ret->body_.all_identifiers);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.procedures");
ASSERT_TRUE(call_proc->arguments_.empty());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
ASSERT_THAT(identifier_names, UnorderedElementsAre("name", "signature", "is_write", "path", "is_editable"));
ASSERT_EQ(identifier_names, call_proc->result_fields_);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithoutYield) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.load_all()"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.load_all");
ASSERT_TRUE(call_proc->arguments_.empty());
ASSERT_TRUE(call_proc->result_fields_.empty());
ASSERT_TRUE(call_proc->result_identifiers_.empty());
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithMemoryLimitWithoutYield) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.load_all() PROCEDURE MEMORY LIMIT 32 KB"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.load_all");
ASSERT_TRUE(call_proc->arguments_.empty());
ASSERT_TRUE(call_proc->result_fields_.empty());
ASSERT_TRUE(call_proc->result_identifiers_.empty());
ast_generator.CheckLiteral(call_proc->memory_limit_, 32);
ASSERT_EQ(call_proc->memory_scale_, 1024);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithMemoryUnlimitedWithoutYield) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.load_all() PROCEDURE MEMORY UNLIMITED"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.load_all");
ASSERT_TRUE(call_proc->arguments_.empty());
ASSERT_TRUE(call_proc->result_fields_.empty());
ASSERT_TRUE(call_proc->result_identifiers_.empty());
ASSERT_FALSE(call_proc->memory_limit_);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithMemoryLimit) {
auto &ast_generator = *GetParam();
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("CALL mg.load_all() PROCEDURE MEMORY LIMIT 32 MB YIELD res"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.load_all");
ASSERT_TRUE(call_proc->arguments_.empty());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> expected_names{"res"};
ASSERT_EQ(identifier_names, expected_names);
ASSERT_EQ(identifier_names, call_proc->result_fields_);
ast_generator.CheckLiteral(call_proc->memory_limit_, 32);
ASSERT_EQ(call_proc->memory_scale_, 1024 * 1024);
}
TEST_P(CypherMainVisitorTest, CallProcedureWithMemoryUnlimited) {
auto &ast_generator = *GetParam();
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.load_all() PROCEDURE MEMORY UNLIMITED YIELD res"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc);
ASSERT_EQ(call_proc->procedure_name_, "mg.load_all");
ASSERT_TRUE(call_proc->arguments_.empty());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
ASSERT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> expected_names{"res"};
ASSERT_EQ(identifier_names, expected_names);
ASSERT_EQ(identifier_names, call_proc->result_fields_);
ASSERT_FALSE(call_proc->memory_limit_);
}
namespace {
template <typename TException = SyntaxException>
void TestInvalidQuery(const auto &query, Base &ast_generator) {
SCOPED_TRACE(query);
EXPECT_THROW(ast_generator.ParseQuery(query), TException) << query;
}
template <typename TException = SyntaxException>
void TestInvalidQueryWithMessage(const auto &query, Base &ast_generator, const std::string_view message) {
bool exception_is_thrown = false;
try {
ast_generator.ParseQuery(query);
} catch (const TException &se) {
EXPECT_EQ(std::string_view{se.what()}, message);
exception_is_thrown = true;
} catch (...) {
FAIL() << "Unexpected exception";
}
EXPECT_TRUE(exception_is_thrown);
}
void CheckParsedCallProcedure(const CypherQuery &query, Base &ast_generator,
const std::string_view fully_qualified_proc_name,
const std::vector<std::string_view> &args, const ProcedureType type,
const size_t clauses_size, const size_t call_procedure_index) {
ASSERT_NE(query.single_query_, nullptr);
auto *single_query = query.single_query_;
EXPECT_EQ(single_query->clauses_.size(), clauses_size);
ASSERT_FALSE(single_query->clauses_.empty());
ASSERT_LT(call_procedure_index, clauses_size);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[call_procedure_index]);
ASSERT_NE(call_proc, nullptr);
EXPECT_EQ(call_proc->procedure_name_, fully_qualified_proc_name);
EXPECT_TRUE(call_proc->arguments_.empty());
EXPECT_EQ(call_proc->result_fields_.size(), 2U);
EXPECT_EQ(call_proc->result_identifiers_.size(), call_proc->result_fields_.size());
std::vector<std::string> identifier_names;
identifier_names.reserve(call_proc->result_identifiers_.size());
for (const auto *identifier : call_proc->result_identifiers_) {
EXPECT_TRUE(identifier->user_declared_);
identifier_names.push_back(identifier->name_);
}
std::vector<std::string> args_as_str{};
std::transform(args.begin(), args.end(), std::back_inserter(args_as_str),
[](const std::string_view arg) { return std::string{arg}; });
EXPECT_EQ(identifier_names, args_as_str);
EXPECT_EQ(identifier_names, call_proc->result_fields_);
ASSERT_EQ(call_proc->is_write_, type == ProcedureType::WRITE);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
};
} // namespace
TEST_P(CypherMainVisitorTest, CallProcedureMultipleQueryPartsAfter) {
auto &ast_generator = *GetParam();
static constexpr std::string_view fst{"fst"};
static constexpr std::string_view snd{"snd"};
const std::vector args{fst, snd};
const auto read_proc = CreateProcByType(ProcedureType::READ, args);
const auto write_proc = CreateProcByType(ProcedureType::WRITE, args);
const auto check_parsed_call_proc = [&ast_generator, &args](const CypherQuery &query,
const std::string_view fully_qualified_proc_name,
const ProcedureType type, const size_t clause_size) {
CheckParsedCallProcedure(query, ast_generator, fully_qualified_proc_name, args, type, clause_size, 0);
};
{
SCOPED_TRACE("Read query part");
{
SCOPED_TRACE("With WITH");
static constexpr std::string_view kQueryWithWith{"CALL {}() YIELD {},{} WITH {},{} UNWIND {} as u RETURN u"};
static constexpr size_t kQueryParts{4};
{
SCOPED_TRACE("Write proc");
const auto query_str = fmt::format(kQueryWithWith, write_proc, fst, snd, fst, snd, fst);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator,
"WITH can't be put after calling a writeable procedure, only RETURN clause can be put after.");
}
{
SCOPED_TRACE("Read proc");
const auto query_str = fmt::format(kQueryWithWith, read_proc, fst, snd, fst, snd, fst);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, read_proc, ProcedureType::READ, kQueryParts);
}
}
{
SCOPED_TRACE("Without WITH");
static constexpr std::string_view kQueryWithoutWith{"CALL {}() YIELD {},{} UNWIND {} as u RETURN u"};
static constexpr size_t kQueryParts{3};
{
SCOPED_TRACE("Write proc");
const auto query_str = fmt::format(kQueryWithoutWith, write_proc, fst, snd, fst);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator,
"UNWIND can't be put after calling a writeable procedure, only RETURN clause can be put after.");
}
{
SCOPED_TRACE("Read proc");
const auto query_str = fmt::format(kQueryWithoutWith, read_proc, fst, snd, fst);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, read_proc, ProcedureType::READ, kQueryParts);
}
}
}
{
SCOPED_TRACE("Write query part");
{
SCOPED_TRACE("With WITH");
static constexpr std::string_view kQueryWithWith{
"CALL {}() YIELD {},{} WITH {},{} CREATE(n {{prop : {}}}) RETURN n"};
static constexpr size_t kQueryParts{4};
{
SCOPED_TRACE("Write proc");
const auto query_str = fmt::format(kQueryWithWith, write_proc, fst, snd, fst, snd, fst);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator,
"WITH can't be put after calling a writeable procedure, only RETURN clause can be put after.");
}
{
SCOPED_TRACE("Read proc");
const auto query_str = fmt::format(kQueryWithWith, read_proc, fst, snd, fst, snd, fst);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, read_proc, ProcedureType::READ, kQueryParts);
}
}
{
SCOPED_TRACE("Without WITH");
static constexpr std::string_view kQueryWithoutWith{"CALL {}() YIELD {},{} CREATE(n {{prop : {}}}) RETURN n"};
static constexpr size_t kQueryParts{3};
{
SCOPED_TRACE("Write proc");
const auto query_str = fmt::format(kQueryWithoutWith, write_proc, fst, snd, fst);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator,
"Update clause can't be put after calling a writeable procedure, only RETURN clause can be put after.");
}
{
SCOPED_TRACE("Read proc");
const auto query_str = fmt::format(kQueryWithoutWith, read_proc, fst, snd, fst, snd, fst);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, read_proc, ProcedureType::READ, kQueryParts);
}
}
}
}
TEST_P(CypherMainVisitorTest, CallProcedureMultipleQueryPartsBefore) {
auto &ast_generator = *GetParam();
static constexpr std::string_view fst{"fst"};
static constexpr std::string_view snd{"snd"};
const std::vector args{fst, snd};
const auto read_proc = CreateProcByType(ProcedureType::READ, args);
const auto write_proc = CreateProcByType(ProcedureType::WRITE, args);
const auto check_parsed_call_proc = [&ast_generator, &args](const CypherQuery &query,
const std::string_view fully_qualified_proc_name,
const ProcedureType type, const size_t clause_size) {
CheckParsedCallProcedure(query, ast_generator, fully_qualified_proc_name, args, type, clause_size, clause_size - 2);
};
{
SCOPED_TRACE("Read query part");
static constexpr std::string_view kQueryWithReadQueryPart{"MATCH (n) CALL {}() YIELD * RETURN *"};
static constexpr size_t kQueryParts{3};
{
SCOPED_TRACE("Write proc");
const auto query_str = fmt::format(kQueryWithReadQueryPart, write_proc);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, write_proc, ProcedureType::WRITE, kQueryParts);
}
{
SCOPED_TRACE("Read proc");
const auto query_str = fmt::format(kQueryWithReadQueryPart, read_proc);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, read_proc, ProcedureType::READ, kQueryParts);
}
}
{
SCOPED_TRACE("Write query part");
static constexpr std::string_view kQueryWithWriteQueryPart{"CREATE (n) WITH n CALL {}() YIELD * RETURN *"};
static constexpr size_t kQueryParts{4};
{
SCOPED_TRACE("Write proc");
const auto query_str = fmt::format(kQueryWithWriteQueryPart, write_proc, fst, snd, fst);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator, "Write procedures cannot be used in queries that contains any update clauses!");
}
{
SCOPED_TRACE("Read proc");
const auto query_str = fmt::format(kQueryWithWriteQueryPart, read_proc, fst, snd, fst, snd, fst);
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
check_parsed_call_proc(*query, read_proc, ProcedureType::READ, kQueryParts);
}
}
}
TEST_P(CypherMainVisitorTest, CallProcedureMultipleProcedures) {
auto &ast_generator = *GetParam();
static constexpr std::string_view fst{"fst"};
static constexpr std::string_view snd{"snd"};
const std::vector args{fst, snd};
const auto read_proc = CreateProcByType(ProcedureType::READ, args);
const auto write_proc = CreateProcByType(ProcedureType::WRITE, args);
{
SCOPED_TRACE("Read then write");
const auto query_str = fmt::format("CALL {}() YIELD * CALL {}() YIELD * RETURN *", read_proc, write_proc);
static constexpr size_t kQueryParts{3};
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query_str));
ASSERT_NE(query, nullptr);
CheckParsedCallProcedure(*query, ast_generator, read_proc, args, ProcedureType::READ, kQueryParts, 0);
CheckParsedCallProcedure(*query, ast_generator, write_proc, args, ProcedureType::WRITE, kQueryParts, 1);
}
{
SCOPED_TRACE("Write then read");
const auto query_str = fmt::format("CALL {}() YIELD * CALL {}() YIELD * RETURN *", write_proc, read_proc);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator,
"CALL can't be put after calling a writeable procedure, only RETURN clause can be put after.");
}
{
SCOPED_TRACE("Write twice");
const auto query_str = fmt::format("CALL {}() YIELD * CALL {}() YIELD * RETURN *", write_proc, write_proc);
TestInvalidQueryWithMessage<SemanticException>(
query_str, ast_generator,
"CALL can't be put after calling a writeable procedure, only RETURN clause can be put after.");
}
}
TEST_P(CypherMainVisitorTest, IncorrectCallProcedure) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("CALL proc-with-dashes()"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc() yield field-with-dashes"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc() yield field.with.dots"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc() yield res AS result-with-dashes"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc() yield res AS result.with.dots"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("WITH 42 AS x CALL not_standalone(x)"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("CALL procedure() YIELD"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 42, CALL procedure() YIELD"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 42, CALL procedure() YIELD res"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN 42 AS x CALL procedure() YIELD res"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc.with.dots() MEMORY YIELD res"), SyntaxException);
// mg.procedures returns something, so it needs to have a YIELD.
ASSERT_THROW(ast_generator.ParseQuery("CALL mg.procedures()"), SemanticException);
ASSERT_THROW(ast_generator.ParseQuery("CALL mg.procedures() PROCEDURE MEMORY UNLIMITED"), SemanticException);
// TODO: Implement support for the following syntax. These are defined in
// Neo4j and accepted in openCypher CIP.
ASSERT_THROW(ast_generator.ParseQuery("CALL proc"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc RETURN 42"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc() YIELD res WHERE res > 42"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("CALL proc() YIELD res WHERE res > 42 RETURN *"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, TestLockPathQuery) {
auto &ast_generator = *GetParam();
const auto test_lock_path_query = [&](const std::string_view command, const LockPathQuery::Action action) {
ASSERT_THROW(ast_generator.ParseQuery(command.data()), SyntaxException);
{
const std::string query = fmt::format("{} ME", command);
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = fmt::format("{} DATA", command);
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = fmt::format("{} DATA STUFF", command);
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = fmt::format("{} DATA DIRECTORY", command);
auto *parsed_query = dynamic_cast<LockPathQuery *>(ast_generator.ParseQuery(query));
ASSERT_TRUE(parsed_query);
EXPECT_EQ(parsed_query->action_, action);
}
{
const std::string query = fmt::format("{} DATA DIRECTORY LOCK STATUS", command);
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = fmt::format("{} DATA DIRECTORY STATUS", command);
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
};
test_lock_path_query("LOCK", LockPathQuery::Action::LOCK_PATH);
test_lock_path_query("UNLOCK", LockPathQuery::Action::UNLOCK_PATH);
// Status test
{
const std::string query = "DATA DIRECTORY LOCK";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = "DATA LOCK STATUS";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = "DIRECTORY LOCK STATUS";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = "DATA DIRECTORY LOCK STATUS";
auto *parsed_query = dynamic_cast<LockPathQuery *>(ast_generator.ParseQuery(query));
ASSERT_TRUE(parsed_query);
EXPECT_EQ(parsed_query->action_, LockPathQuery::Action::STATUS);
}
}
TEST_P(CypherMainVisitorTest, TestLoadCsvClause) {
auto &ast_generator = *GetParam();
{
const std::string query = R"(LOAD CSV FROM "file.csv")";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH)";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER)";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER DELIMITER ";")";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER DELIMITER ";" QUOTE "'")";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER DELIMITER ";" QUOTE "'" AS)";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM file WITH HEADER IGNORE BAD DELIMITER ";" QUOTE "'" AS x)";
ASSERT_THROW(ast_generator.ParseQuery(query), SyntaxException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER IGNORE BAD DELIMITER 0 QUOTE "'" AS x)";
ASSERT_THROW(ast_generator.ParseQuery(query), SemanticException);
}
{
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER IGNORE BAD DELIMITER ";" QUOTE 0 AS x)";
ASSERT_THROW(ast_generator.ParseQuery(query), SemanticException);
}
{
// can't be a standalone clause
const std::string query = R"(LOAD CSV FROM "file.csv" WITH HEADER IGNORE BAD DELIMITER ";" QUOTE "'" AS x)";
ASSERT_THROW(ast_generator.ParseQuery(query), SemanticException);
}
{
const std::string query =
R"(LOAD CSV FROM "file.csv" WITH HEADER IGNORE BAD DELIMITER ";" QUOTE "'" AS x RETURN x)";
auto *parsed_query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(query));
ASSERT_TRUE(parsed_query);
auto *load_csv_clause = dynamic_cast<LoadCsv *>(parsed_query->single_query_->clauses_[0]);
ASSERT_TRUE(load_csv_clause);
ASSERT_TRUE(load_csv_clause->with_header_);
ASSERT_TRUE(load_csv_clause->ignore_bad_);
}
}
TEST_P(CypherMainVisitorTest, MemoryLimit) {
auto &ast_generator = *GetParam();
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUE"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY MEM"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY MEMORY"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY MEMORY LIM"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY MEMORY LIMIT"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY MEMORY LIMIT KB"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("RETURN x QUERY MEMORY LIMIT 12GB"), SyntaxException);
ASSERT_THROW(ast_generator.ParseQuery("QUERY MEMORY LIMIT 12KB RETURN x"), SyntaxException);
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x"));
ASSERT_TRUE(query);
ASSERT_FALSE(query->memory_limit_);
}
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x QUERY MEMORY LIMIT 12KB"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->memory_limit_);
ast_generator.CheckLiteral(query->memory_limit_, 12);
ASSERT_EQ(query->memory_scale_, 1024U);
}
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("RETURN x QUERY MEMORY LIMIT 12MB"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->memory_limit_);
ast_generator.CheckLiteral(query->memory_limit_, 12);
ASSERT_EQ(query->memory_scale_, 1024U * 1024U);
}
{
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("CALL mg.procedures() YIELD x RETURN x QUERY MEMORY LIMIT 12MB"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->memory_limit_);
ast_generator.CheckLiteral(query->memory_limit_, 12);
ASSERT_EQ(query->memory_scale_, 1024U * 1024U);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(
"CALL mg.procedures() PROCEDURE MEMORY LIMIT 3KB YIELD x RETURN x QUERY MEMORY LIMIT 12MB"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->memory_limit_);
ast_generator.CheckLiteral(query->memory_limit_, 12);
ASSERT_EQ(query->memory_scale_, 1024U * 1024U);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc->memory_limit_);
ast_generator.CheckLiteral(call_proc->memory_limit_, 3);
ASSERT_EQ(call_proc->memory_scale_, 1024U);
}
{
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("CALL mg.procedures() PROCEDURE MEMORY LIMIT 3KB YIELD x RETURN x"));
ASSERT_TRUE(query);
ASSERT_FALSE(query->memory_limit_);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 2U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc->memory_limit_);
ast_generator.CheckLiteral(call_proc->memory_limit_, 3);
ASSERT_EQ(call_proc->memory_scale_, 1024U);
}
{
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.load_all() PROCEDURE MEMORY LIMIT 3KB"));
ASSERT_TRUE(query);
ASSERT_FALSE(query->memory_limit_);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
ASSERT_TRUE(call_proc->memory_limit_);
ast_generator.CheckLiteral(call_proc->memory_limit_, 3);
ASSERT_EQ(call_proc->memory_scale_, 1024U);
}
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("CALL mg.load_all() QUERY MEMORY LIMIT 3KB"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->memory_limit_);
ast_generator.CheckLiteral(query->memory_limit_, 3);
ASSERT_EQ(query->memory_scale_, 1024U);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *call_proc = dynamic_cast<CallProcedure *>(single_query->clauses_[0]);
CheckCallProcedureDefaultMemoryLimit(ast_generator, *call_proc);
}
}
TEST_P(CypherMainVisitorTest, DropTrigger) {
auto &ast_generator = *GetParam();
TestInvalidQuery("DROP TR", ast_generator);
TestInvalidQuery("DROP TRIGGER", ast_generator);
auto *parsed_query = dynamic_cast<TriggerQuery *>(ast_generator.ParseQuery("DROP TRIGGER trigger"));
EXPECT_EQ(parsed_query->action_, TriggerQuery::Action::DROP_TRIGGER);
EXPECT_EQ(parsed_query->trigger_name_, "trigger");
}
TEST_P(CypherMainVisitorTest, ShowTriggers) {
auto &ast_generator = *GetParam();
TestInvalidQuery("SHOW TR", ast_generator);
TestInvalidQuery("SHOW TRIGGER", ast_generator);
auto *parsed_query = dynamic_cast<TriggerQuery *>(ast_generator.ParseQuery("SHOW TRIGGERS"));
EXPECT_EQ(parsed_query->action_, TriggerQuery::Action::SHOW_TRIGGERS);
}
namespace {
void ValidateCreateQuery(Base &ast_generator, const auto &query, const auto &trigger_name,
const memgraph::query::TriggerQuery::EventType event_type, const auto &phase,
const auto &statement) {
auto *parsed_query = dynamic_cast<TriggerQuery *>(ast_generator.ParseQuery(query));
EXPECT_EQ(parsed_query->action_, TriggerQuery::Action::CREATE_TRIGGER);
EXPECT_EQ(parsed_query->trigger_name_, trigger_name);
EXPECT_EQ(parsed_query->event_type_, event_type);
EXPECT_EQ(parsed_query->before_commit_, phase == "BEFORE");
EXPECT_EQ(parsed_query->statement_, statement);
}
} // namespace
TEST_P(CypherMainVisitorTest, CreateTriggers) {
auto &ast_generator = *GetParam();
TestInvalidQuery("CREATE TRIGGER", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON ", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON ()", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON -->", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON CREATE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON () CREATE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON --> CREATE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON DELETE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON () DELETE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON --> DELETE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON UPDATE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON () UPDATE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON --> UPDATE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON CREATE BEFORE", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON CREATE BEFORE COMMIT", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON CREATE AFTER", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON CREATE AFTER COMMIT", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON -> CREATE AFTER COMMIT EXECUTE a", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON ) CREATE AFTER COMMIT EXECUTE a", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON ( CREATE AFTER COMMIT EXECUTE a", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON CRETE AFTER COMMIT EXECUTE a", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON DELET AFTER COMMIT EXECUTE a", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON UPDTE AFTER COMMIT EXECUTE a", ast_generator);
TestInvalidQuery("CREATE TRIGGER trigger ON UPDATE COMMIT EXECUTE a", ast_generator);
static constexpr std::string_view query_template = "CREATE TRIGGER trigger {} {} COMMIT EXECUTE {}";
static constexpr std::array events{std::pair{"", memgraph::query::TriggerQuery::EventType::ANY},
std::pair{"ON CREATE", memgraph::query::TriggerQuery::EventType::CREATE},
std::pair{"ON () CREATE", memgraph::query::TriggerQuery::EventType::VERTEX_CREATE},
std::pair{"ON --> CREATE", memgraph::query::TriggerQuery::EventType::EDGE_CREATE},
std::pair{"ON DELETE", memgraph::query::TriggerQuery::EventType::DELETE},
std::pair{"ON () DELETE", memgraph::query::TriggerQuery::EventType::VERTEX_DELETE},
std::pair{"ON --> DELETE", memgraph::query::TriggerQuery::EventType::EDGE_DELETE},
std::pair{"ON UPDATE", memgraph::query::TriggerQuery::EventType::UPDATE},
std::pair{"ON () UPDATE", memgraph::query::TriggerQuery::EventType::VERTEX_UPDATE},
std::pair{"ON --> UPDATE", memgraph::query::TriggerQuery::EventType::EDGE_UPDATE}};
static constexpr std::array phases{"BEFORE", "AFTER"};
static constexpr std::array statements{
"", "SOME SUPER\nSTATEMENT", "Statement with 12312321 3 ", " Statement with 12312321 3 "
};
for (const auto &[event_string, event_type] : events) {
for (const auto &phase : phases) {
for (const auto &statement : statements) {
ValidateCreateQuery(ast_generator, fmt::format(query_template, event_string, phase, statement), "trigger",
event_type, phase, memgraph::utils::Trim(statement));
}
}
}
}
namespace {
void ValidateSetIsolationLevelQuery(Base &ast_generator, const auto &query, const auto scope,
const auto isolation_level) {
auto *parsed_query = dynamic_cast<IsolationLevelQuery *>(ast_generator.ParseQuery(query));
EXPECT_EQ(parsed_query->isolation_level_scope_, scope);
EXPECT_EQ(parsed_query->isolation_level_, isolation_level);
}
} // namespace
TEST_P(CypherMainVisitorTest, SetIsolationLevelQuery) {
auto &ast_generator = *GetParam();
TestInvalidQuery("SET ISO", ast_generator);
TestInvalidQuery("SET TRANSACTION ISOLATION", ast_generator);
TestInvalidQuery("SET TRANSACTION ISOLATION LEVEL", ast_generator);
TestInvalidQuery("SET TRANSACTION ISOLATION LEVEL READ COMMITTED", ast_generator);
TestInvalidQuery("SET NEXT TRANSACTION ISOLATION LEVEL", ast_generator);
TestInvalidQuery("SET ISOLATION LEVEL READ COMMITTED", ast_generator);
TestInvalidQuery("SET GLOBAL ISOLATION LEVEL READ COMMITTED", ast_generator);
TestInvalidQuery("SET GLOBAL TRANSACTION ISOLATION LEVEL READ COMITTED", ast_generator);
TestInvalidQuery("SET GLOBAL TRANSACTION ISOLATION LEVEL READ_COMITTED", ast_generator);
TestInvalidQuery("SET SESSION TRANSACTION ISOLATION LEVEL READCOMITTED", ast_generator);
static constexpr std::array scopes{
std::pair{"GLOBAL", memgraph::query::IsolationLevelQuery::IsolationLevelScope::GLOBAL},
std::pair{"SESSION", memgraph::query::IsolationLevelQuery::IsolationLevelScope::SESSION},
std::pair{"NEXT", memgraph::query::IsolationLevelQuery::IsolationLevelScope::NEXT}};
static constexpr std::array isolation_levels{
std::pair{"READ UNCOMMITTED", memgraph::query::IsolationLevelQuery::IsolationLevel::READ_UNCOMMITTED},
std::pair{"READ COMMITTED", memgraph::query::IsolationLevelQuery::IsolationLevel::READ_COMMITTED},
std::pair{"SNAPSHOT ISOLATION", memgraph::query::IsolationLevelQuery::IsolationLevel::SNAPSHOT_ISOLATION}};
static constexpr const auto *query_template = "SET {} TRANSACTION ISOLATION LEVEL {}";
for (const auto &[scope_string, scope] : scopes) {
for (const auto &[isolation_level_string, isolation_level] : isolation_levels) {
ValidateSetIsolationLevelQuery(ast_generator, fmt::format(query_template, scope_string, isolation_level_string),
scope, isolation_level);
}
}
}
TEST_P(CypherMainVisitorTest, CreateSnapshotQuery) {
auto &ast_generator = *GetParam();
ASSERT_TRUE(dynamic_cast<CreateSnapshotQuery *>(ast_generator.ParseQuery("CREATE SNAPSHOT")));
}
void CheckOptionalExpression(Base &ast_generator, Expression *expression, const std::optional<TypedValue> &expected) {
EXPECT_EQ(expression != nullptr, expected.has_value());
if (expected.has_value()) {
EXPECT_NO_FATAL_FAILURE(ast_generator.CheckLiteral(expression, *expected));
}
};
void ValidateMostlyEmptyStreamQuery(Base &ast_generator, const std::string &query_string,
const StreamQuery::Action action, const std::string_view stream_name,
const std::optional<TypedValue> &batch_limit = std::nullopt,
const std::optional<TypedValue> &timeout = std::nullopt) {
auto *parsed_query = dynamic_cast<StreamQuery *>(ast_generator.ParseQuery(query_string));
ASSERT_NE(parsed_query, nullptr);
EXPECT_EQ(parsed_query->action_, action);
EXPECT_EQ(parsed_query->stream_name_, stream_name);
auto topic_names = std::get_if<Expression *>(&parsed_query->topic_names_);
EXPECT_NE(topic_names, nullptr);
EXPECT_EQ(*topic_names, nullptr);
EXPECT_TRUE(topic_names);
EXPECT_FALSE(*topic_names);
EXPECT_TRUE(parsed_query->transform_name_.empty());
EXPECT_TRUE(parsed_query->consumer_group_.empty());
EXPECT_EQ(parsed_query->batch_interval_, nullptr);
EXPECT_EQ(parsed_query->batch_size_, nullptr);
EXPECT_EQ(parsed_query->service_url_, nullptr);
EXPECT_EQ(parsed_query->bootstrap_servers_, nullptr);
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->batch_limit_, batch_limit));
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->timeout_, timeout));
EXPECT_TRUE(parsed_query->configs_.empty());
EXPECT_TRUE(parsed_query->credentials_.empty());
}
TEST_P(CypherMainVisitorTest, DropStream) {
auto &ast_generator = *GetParam();
TestInvalidQuery("DROP ST", ast_generator);
TestInvalidQuery("DROP STREAM", ast_generator);
TestInvalidQuery("DROP STREAMS", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "DrOP STREAm droppedStream", StreamQuery::Action::DROP_STREAM,
"droppedStream");
}
TEST_P(CypherMainVisitorTest, StartStream) {
auto &ast_generator = *GetParam();
TestInvalidQuery("START ST", ast_generator);
TestInvalidQuery("START STREAM", ast_generator);
TestInvalidQuery("START STREAMS", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "START STREAM startedStream", StreamQuery::Action::START_STREAM,
"startedStream");
}
TEST_P(CypherMainVisitorTest, StartAllStreams) {
auto &ast_generator = *GetParam();
TestInvalidQuery("START ALL", ast_generator);
TestInvalidQuery("START ALL STREAM", ast_generator);
TestInvalidQuery("START STREAMS ALL", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "StARt AlL StrEAMS", StreamQuery::Action::START_ALL_STREAMS, "");
}
TEST_P(CypherMainVisitorTest, ShowStreams) {
auto &ast_generator = *GetParam();
TestInvalidQuery("SHOW ALL", ast_generator);
TestInvalidQuery("SHOW STREAM", ast_generator);
TestInvalidQuery("SHOW STREAMS ALL", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "SHOW STREAMS", StreamQuery::Action::SHOW_STREAMS, "");
}
TEST_P(CypherMainVisitorTest, StopStream) {
auto &ast_generator = *GetParam();
TestInvalidQuery("STOP ST", ast_generator);
TestInvalidQuery("STOP STREAM", ast_generator);
TestInvalidQuery("STOP STREAMS", ast_generator);
TestInvalidQuery("STOP STREAM invalid stream name", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "STOP stREAM stoppedStream", StreamQuery::Action::STOP_STREAM,
"stoppedStream");
}
TEST_P(CypherMainVisitorTest, StopAllStreams) {
auto &ast_generator = *GetParam();
TestInvalidQuery("STOP ALL", ast_generator);
TestInvalidQuery("STOP ALL STREAM", ast_generator);
TestInvalidQuery("STOP STREAMS ALL", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "SToP ALL STReaMS", StreamQuery::Action::STOP_ALL_STREAMS, "");
}
void ValidateTopicNames(const auto &topic_names, const std::vector<std::string> &expected_topic_names,
Base &ast_generator) {
std::visit(memgraph::utils::Overloaded{
[&](Expression *expression) {
ast_generator.CheckLiteral(expression, memgraph::utils::Join(expected_topic_names, ","));
},
[&](const std::vector<std::string> &topic_names) { EXPECT_EQ(topic_names, expected_topic_names); }},
topic_names);
}
void ValidateCreateKafkaStreamQuery(Base &ast_generator, const std::string &query_string,
const std::string_view stream_name, const std::vector<std::string> &topic_names,
const std::string_view transform_name, const std::string_view consumer_group,
const std::optional<TypedValue> &batch_interval,
const std::optional<TypedValue> &batch_size,
const std::string_view bootstrap_servers,
const std::unordered_map<std::string, std::string> &configs,
const std::unordered_map<std::string, std::string> &credentials) {
SCOPED_TRACE(query_string);
StreamQuery *parsed_query{nullptr};
ASSERT_NO_THROW(parsed_query = dynamic_cast<StreamQuery *>(ast_generator.ParseQuery(query_string))) << query_string;
ASSERT_NE(parsed_query, nullptr);
EXPECT_EQ(parsed_query->stream_name_, stream_name);
ValidateTopicNames(parsed_query->topic_names_, topic_names, ast_generator);
EXPECT_EQ(parsed_query->transform_name_, transform_name);
EXPECT_EQ(parsed_query->consumer_group_, consumer_group);
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->batch_interval_, batch_interval));
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->batch_size_, batch_size));
EXPECT_EQ(parsed_query->batch_limit_, nullptr);
if (bootstrap_servers.empty()) {
EXPECT_EQ(parsed_query->bootstrap_servers_, nullptr);
} else {
EXPECT_NE(parsed_query->bootstrap_servers_, nullptr);
}
const auto evaluate_config_map = [&ast_generator](const std::unordered_map<Expression *, Expression *> &config_map) {
std::unordered_map<std::string, std::string> evaluated_config_map;
const auto expr_to_str = [&ast_generator](Expression *expression) {
return std::string{ast_generator.GetLiteral(expression, ast_generator.context_.is_query_cached).ValueString()};
};
std::transform(config_map.begin(), config_map.end(),
std::inserter(evaluated_config_map, evaluated_config_map.end()),
[&expr_to_str](const auto expr_pair) {
return std::pair{expr_to_str(expr_pair.first), expr_to_str(expr_pair.second)};
});
return evaluated_config_map;
};
using testing::UnorderedElementsAreArray;
EXPECT_THAT(evaluate_config_map(parsed_query->configs_), UnorderedElementsAreArray(configs.begin(), configs.end()));
EXPECT_THAT(evaluate_config_map(parsed_query->credentials_),
UnorderedElementsAreArray(credentials.begin(), credentials.end()));
}
TEST_P(CypherMainVisitorTest, CreateKafkaStream) {
auto &ast_generator = *GetParam();
TestInvalidQuery("CREATE KAFKA STREAM", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM invalid stream name TOPICS topic1 TRANSFORM transform", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS invalid topic name TRANSFORM transform", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM invalid transformation name", ast_generator);
// required configs are missing
TestInvalidQuery<SemanticException>("CREATE KAFKA STREAM stream TRANSFORM transform", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS TRANSFORM transform", ast_generator);
// required configs are missing
TestInvalidQuery<SemanticException>("CREATE KAFKA STREAM stream TOPICS topic1", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform CONSUMER_GROUP", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform CONSUMER_GROUP invalid consumer group",
ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform BATCH_INTERVAL", ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform BATCH_INTERVAL 'invalid interval'", ast_generator);
TestInvalidQuery<SemanticException>("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform TOPICS topic2",
ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform BATCH_SIZE", ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform BATCH_SIZE 'invalid size'", ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1, TRANSFORM transform BATCH_SIZE 2 CONSUMER_GROUP Gru",
ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform BOOTSTRAP_SERVERS localhost:9092",
ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform BOOTSTRAP_SERVERS", ast_generator);
// the keys must be string literals
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform CONFIGS { symbolicname : 'string' }",
ast_generator);
TestInvalidQuery(
"CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform CREDENTIALS { symbolicname : 'string' }",
ast_generator);
TestInvalidQuery("CREATE KAFKA STREAM stream TOPICS topic1 TRANSFORM transform CREDENTIALS 2", ast_generator);
const std::vector<std::string> topic_names{"topic1_name.with_dot", "topic1_name.with_multiple.dots",
"topic-name.with-multiple.dots-and-dashes"};
static constexpr std::string_view kStreamName{"SomeSuperStream"};
static constexpr std::string_view kTransformName{"moreAwesomeTransform"};
auto check_topic_names = [&](const std::vector<std::string> &topic_names) {
static constexpr std::string_view kConsumerGroup{"ConsumerGru"};
static constexpr int kBatchInterval = 324;
const TypedValue batch_interval_value{kBatchInterval};
static constexpr int kBatchSize = 1;
const TypedValue batch_size_value{kBatchSize};
const auto topic_names_as_str = memgraph::utils::Join(topic_names, ",");
ValidateCreateKafkaStreamQuery(
ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} TRANSFORM {}", kStreamName, topic_names_as_str, kTransformName),
kStreamName, topic_names, kTransformName, "", std::nullopt, std::nullopt, {}, {}, {});
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} TRANSFORM {} CONSUMER_GROUP {} ",
kStreamName, topic_names_as_str, kTransformName, kConsumerGroup),
kStreamName, topic_names, kTransformName, kConsumerGroup, std::nullopt, std::nullopt,
{}, {}, {});
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} TRANSFORM {} TOPICS {} BATCH_INTERVAL {}",
kStreamName, kTransformName, topic_names_as_str, kBatchInterval),
kStreamName, topic_names, kTransformName, "", batch_interval_value, std::nullopt, {},
{}, {});
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} BATCH_SIZE {} TOPICS {} TRANSFORM {}",
kStreamName, kBatchSize, topic_names_as_str, kTransformName),
kStreamName, topic_names, kTransformName, "", std::nullopt, batch_size_value, {}, {},
{});
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS '{}' BATCH_SIZE {} TRANSFORM {}",
kStreamName, topic_names_as_str, kBatchSize, kTransformName),
kStreamName, topic_names, kTransformName, "", std::nullopt, batch_size_value, {}, {},
{});
ValidateCreateKafkaStreamQuery(
ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} TRANSFORM {} CONSUMER_GROUP {} BATCH_INTERVAL {} BATCH_SIZE {}",
kStreamName, topic_names_as_str, kTransformName, kConsumerGroup, kBatchInterval, kBatchSize),
kStreamName, topic_names, kTransformName, kConsumerGroup, batch_interval_value, batch_size_value, {}, {}, {});
using namespace std::string_literals;
const auto host1 = "localhost:9094"s;
ValidateCreateKafkaStreamQuery(
ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} CONSUMER_GROUP {} BATCH_SIZE {} BATCH_INTERVAL {} TRANSFORM {} "
"BOOTSTRAP_SERVERS '{}'",
kStreamName, topic_names_as_str, kConsumerGroup, kBatchSize, kBatchInterval, kTransformName, host1),
kStreamName, topic_names, kTransformName, kConsumerGroup, batch_interval_value, batch_size_value, host1, {},
{});
ValidateCreateKafkaStreamQuery(
ast_generator,
fmt::format("CREATE KAFKA STREAM {} CONSUMER_GROUP {} TOPICS {} BATCH_INTERVAL {} TRANSFORM {} BATCH_SIZE {} "
"BOOTSTRAP_SERVERS '{}'",
kStreamName, kConsumerGroup, topic_names_as_str, kBatchInterval, kTransformName, kBatchSize, host1),
kStreamName, topic_names, kTransformName, kConsumerGroup, batch_interval_value, batch_size_value, host1, {},
{});
const auto host2 = "localhost:9094,localhost:1994,168.1.1.256:345"s;
ValidateCreateKafkaStreamQuery(
ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} BOOTSTRAP_SERVERS '{}' CONSUMER_GROUP {} TRANSFORM {} "
"BATCH_INTERVAL {} BATCH_SIZE {}",
kStreamName, topic_names_as_str, host2, kConsumerGroup, kTransformName, kBatchInterval, kBatchSize),
kStreamName, topic_names, kTransformName, kConsumerGroup, batch_interval_value, batch_size_value, host2, {},
{});
};
for (const auto &topic_name : topic_names) {
EXPECT_NO_FATAL_FAILURE(check_topic_names({topic_name}));
}
EXPECT_NO_FATAL_FAILURE(check_topic_names(topic_names));
auto check_consumer_group = [&](const std::string_view consumer_group) {
const std::string kTopicName{"topic1"};
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} TRANSFORM {} CONSUMER_GROUP {}",
kStreamName, kTopicName, kTransformName, consumer_group),
kStreamName, {kTopicName}, kTransformName, consumer_group, std::nullopt,
std::nullopt, {}, {}, {});
};
using namespace std::literals;
static constexpr std::array consumer_groups{"consumergru"sv, "consumer-group-with-dash"sv,
"consumer_group.with.dot"sv, "consumer-group.With-Dot-and.dash"sv};
for (const auto consumer_group : consumer_groups) {
EXPECT_NO_FATAL_FAILURE(check_consumer_group(consumer_group));
}
auto check_config_map = [&](const std::unordered_map<std::string, std::string> &config_map) {
const std::string kTopicName{"topic1"};
const auto map_as_str = std::invoke([&config_map] {
std::stringstream buffer;
buffer << '{';
if (!config_map.empty()) {
auto it = config_map.begin();
buffer << fmt::format("'{}': '{}'", it->first, it->second);
for (; it != config_map.end(); ++it) {
buffer << fmt::format(", '{}': '{}'", it->first, it->second);
}
}
buffer << '}';
return std::move(buffer).str();
});
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} TRANSFORM {} CONFIGS {}", kStreamName,
kTopicName, kTransformName, map_as_str),
kStreamName, {kTopicName}, kTransformName, "", std::nullopt, std::nullopt, {},
config_map, {});
ValidateCreateKafkaStreamQuery(ast_generator,
fmt::format("CREATE KAFKA STREAM {} TOPICS {} TRANSFORM {} CREDENTIALS {}",
kStreamName, kTopicName, kTransformName, map_as_str),
kStreamName, {kTopicName}, kTransformName, "", std::nullopt, std::nullopt, {}, {},
config_map);
};
const std::array config_maps = {std::unordered_map<std::string, std::string>{},
std::unordered_map<std::string, std::string>{{"key", "value"}},
std::unordered_map<std::string, std::string>{{"key.with.dot", "value.with.doth"},
{"key with space", "value with space"}}};
for (const auto &map_to_test : config_maps) {
EXPECT_NO_FATAL_FAILURE(check_config_map(map_to_test));
}
}
void ValidateCreatePulsarStreamQuery(Base &ast_generator, const std::string &query_string,
const std::string_view stream_name, const std::vector<std::string> &topic_names,
const std::string_view transform_name,
const std::optional<TypedValue> &batch_interval,
const std::optional<TypedValue> &batch_size, const std::string_view service_url) {
SCOPED_TRACE(query_string);
StreamQuery *parsed_query{nullptr};
ASSERT_NO_THROW(parsed_query = dynamic_cast<StreamQuery *>(ast_generator.ParseQuery(query_string))) << query_string;
ASSERT_NE(parsed_query, nullptr);
EXPECT_EQ(parsed_query->stream_name_, stream_name);
ValidateTopicNames(parsed_query->topic_names_, topic_names, ast_generator);
EXPECT_EQ(parsed_query->transform_name_, transform_name);
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->batch_interval_, batch_interval));
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->batch_size_, batch_size));
EXPECT_EQ(parsed_query->batch_limit_, nullptr);
if (service_url.empty()) {
EXPECT_EQ(parsed_query->service_url_, nullptr);
return;
}
EXPECT_NE(parsed_query->service_url_, nullptr);
}
TEST_P(CypherMainVisitorTest, CreatePulsarStream) {
auto &ast_generator = *GetParam();
TestInvalidQuery("CREATE PULSAR STREAM", ast_generator);
TestInvalidQuery<SemanticException>("CREATE PULSAR STREAM stream", ast_generator);
TestInvalidQuery("CREATE PULSAR STREAM stream TOPICS", ast_generator);
TestInvalidQuery<SemanticException>("CREATE PULSAR STREAM stream TOPICS topic_name", ast_generator);
TestInvalidQuery("CREATE PULSAR STREAM stream TOPICS topic_name TRANSFORM", ast_generator);
TestInvalidQuery("CREATE PULSAR STREAM stream TOPICS topic_name TRANSFORM transform.name SERVICE_URL", ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE PULSAR STREAM stream TOPICS topic_name TRANSFORM transform.name SERVICE_URL 1", ast_generator);
TestInvalidQuery(
"CREATE PULSAR STREAM stream TOPICS topic_name TRANSFORM transform.name BOOTSTRAP_SERVERS 'bootstrap'",
ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE PULSAR STREAM stream TOPICS topic_name TRANSFORM transform.name SERVICE_URL 'test' TOPICS topic_name",
ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE PULSAR STREAM stream TRANSFORM transform.name TOPICS topic_name TRANSFORM transform.name SERVICE_URL "
"'test'",
ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE PULSAR STREAM stream BATCH_INTERVAL 1 TOPICS topic_name TRANSFORM transform.name SERVICE_URL 'test' "
"BATCH_INTERVAL 1000",
ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE PULSAR STREAM stream BATCH_INTERVAL 'a' TOPICS topic_name TRANSFORM transform.name SERVICE_URL 'test'",
ast_generator);
TestInvalidQuery<SemanticException>(
"CREATE PULSAR STREAM stream BATCH_SIZE 'a' TOPICS topic_name TRANSFORM transform.name SERVICE_URL 'test'",
ast_generator);
const std::vector<std::string> topic_names{"topic1", "topic2"};
const std::string topic_names_str = memgraph::utils::Join(topic_names, ",");
static constexpr std::string_view kStreamName{"PulsarStream"};
static constexpr std::string_view kTransformName{"boringTransformation"};
static constexpr std::string_view kServiceUrl{"localhost"};
static constexpr int kBatchSize{1000};
static constexpr int kBatchInterval{231321};
{
SCOPED_TRACE("single topic");
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} TOPICS {} TRANSFORM {}", kStreamName, topic_names[0], kTransformName),
kStreamName, {topic_names[0]}, kTransformName, std::nullopt, std::nullopt, "");
}
{
SCOPED_TRACE("multiple topics");
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} TRANSFORM {} TOPICS {}", kStreamName, kTransformName, topic_names_str),
kStreamName, topic_names, kTransformName, std::nullopt, std::nullopt, "");
}
{
SCOPED_TRACE("topic name in string");
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} TRANSFORM {} TOPICS '{}'", kStreamName, kTransformName, topic_names_str),
kStreamName, topic_names, kTransformName, std::nullopt, std::nullopt, "");
}
{
SCOPED_TRACE("service url");
ValidateCreatePulsarStreamQuery(ast_generator,
fmt::format("CREATE PULSAR STREAM {} SERVICE_URL '{}' TRANSFORM {} TOPICS {}",
kStreamName, kServiceUrl, kTransformName, topic_names_str),
kStreamName, topic_names, kTransformName, std::nullopt, std::nullopt, kServiceUrl);
ValidateCreatePulsarStreamQuery(ast_generator,
fmt::format("CREATE PULSAR STREAM {} TRANSFORM {} SERVICE_URL '{}' TOPICS {}",
kStreamName, kTransformName, kServiceUrl, topic_names_str),
kStreamName, topic_names, kTransformName, std::nullopt, std::nullopt, kServiceUrl);
}
{
SCOPED_TRACE("batch size");
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} SERVICE_URL '{}' BATCH_SIZE {} TRANSFORM {} TOPICS {}", kStreamName,
kServiceUrl, kBatchSize, kTransformName, topic_names_str),
kStreamName, topic_names, kTransformName, std::nullopt, TypedValue(kBatchSize), kServiceUrl);
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} TRANSFORM {} SERVICE_URL '{}' TOPICS {} BATCH_SIZE {}", kStreamName,
kTransformName, kServiceUrl, topic_names_str, kBatchSize),
kStreamName, topic_names, kTransformName, std::nullopt, TypedValue(kBatchSize), kServiceUrl);
}
{
SCOPED_TRACE("batch interval");
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} BATCH_INTERVAL {} SERVICE_URL '{}' BATCH_SIZE {} TRANSFORM {} TOPICS {}",
kStreamName, kBatchInterval, kServiceUrl, kBatchSize, kTransformName, topic_names_str),
kStreamName, topic_names, kTransformName, TypedValue(kBatchInterval), TypedValue(kBatchSize), kServiceUrl);
ValidateCreatePulsarStreamQuery(
ast_generator,
fmt::format("CREATE PULSAR STREAM {} TRANSFORM {} SERVICE_URL '{}' BATCH_INTERVAL {} TOPICS {} BATCH_SIZE {}",
kStreamName, kTransformName, kServiceUrl, kBatchInterval, topic_names_str, kBatchSize),
kStreamName, topic_names, kTransformName, TypedValue(kBatchInterval), TypedValue(kBatchSize), kServiceUrl);
}
}
TEST_P(CypherMainVisitorTest, CheckStream) {
auto &ast_generator = *GetParam();
TestInvalidQuery("CHECK STREAM", ast_generator);
TestInvalidQuery("CHECK STREAMS", ast_generator);
TestInvalidQuery("CHECK STREAMS something", ast_generator);
TestInvalidQuery("CHECK STREAM something,something", ast_generator);
TestInvalidQuery("CHECK STREAM something BATCH LIMIT 1", ast_generator);
TestInvalidQuery("CHECK STREAM something BATCH_LIMIT", ast_generator);
TestInvalidQuery("CHECK STREAM something TIMEOUT", ast_generator);
TestInvalidQuery("CHECK STREAM something BATCH_LIMIT 1 TIMEOUT", ast_generator);
TestInvalidQuery<SemanticException>("CHECK STREAM something BATCH_LIMIT 'it should be an integer'", ast_generator);
TestInvalidQuery<SemanticException>("CHECK STREAM something BATCH_LIMIT 2.5", ast_generator);
TestInvalidQuery<SemanticException>("CHECK STREAM something TIMEOUT 'it should be an integer'", ast_generator);
ValidateMostlyEmptyStreamQuery(ast_generator, "CHECK STREAM checkedStream", StreamQuery::Action::CHECK_STREAM,
"checkedStream");
ValidateMostlyEmptyStreamQuery(ast_generator, "CHECK STREAM checkedStream bAtCH_LIMIT 42",
StreamQuery::Action::CHECK_STREAM, "checkedStream", TypedValue(42));
ValidateMostlyEmptyStreamQuery(ast_generator, "CHECK STREAM checkedStream TimEOuT 666",
StreamQuery::Action::CHECK_STREAM, "checkedStream", std::nullopt, TypedValue(666));
ValidateMostlyEmptyStreamQuery(ast_generator, "CHECK STREAM checkedStream BATCH_LIMIT 30 TIMEOUT 444",
StreamQuery::Action::CHECK_STREAM, "checkedStream", TypedValue(30), TypedValue(444));
}
TEST_P(CypherMainVisitorTest, SettingQuery) {
auto &ast_generator = *GetParam();
TestInvalidQuery("SHOW DB SETTINGS", ast_generator);
TestInvalidQuery("SHOW SETTINGS", ast_generator);
TestInvalidQuery("SHOW DATABASE SETTING", ast_generator);
TestInvalidQuery("SHOW DB SETTING 'setting'", ast_generator);
TestInvalidQuery("SHOW SETTING 'setting'", ast_generator);
TestInvalidQuery<SemanticException>("SHOW DATABASE SETTING 1", ast_generator);
TestInvalidQuery("SET SETTING 'setting' TO 'value'", ast_generator);
TestInvalidQuery("SET DB SETTING 'setting' TO 'value'", ast_generator);
TestInvalidQuery<SemanticException>("SET DATABASE SETTING 1 TO 'value'", ast_generator);
TestInvalidQuery<SemanticException>("SET DATABASE SETTING 'setting' TO 2", ast_generator);
const auto validate_setting_query = [&](const auto &query, const auto action,
const std::optional<TypedValue> &expected_setting_name,
const std::optional<TypedValue> &expected_setting_value) {
auto *parsed_query = dynamic_cast<SettingQuery *>(ast_generator.ParseQuery(query));
EXPECT_EQ(parsed_query->action_, action) << query;
EXPECT_NO_FATAL_FAILURE(CheckOptionalExpression(ast_generator, parsed_query->setting_name_, expected_setting_name));
EXPECT_NO_FATAL_FAILURE(
CheckOptionalExpression(ast_generator, parsed_query->setting_value_, expected_setting_value));
};
validate_setting_query("SHOW DATABASE SETTINGS", SettingQuery::Action::SHOW_ALL_SETTINGS, std::nullopt, std::nullopt);
validate_setting_query("SHOW DATABASE SETTING 'setting'", SettingQuery::Action::SHOW_SETTING, TypedValue{"setting"},
std::nullopt);
validate_setting_query("SET DATABASE SETTING 'setting' TO 'value'", SettingQuery::Action::SET_SETTING,
TypedValue{"setting"}, TypedValue{"value"});
}
TEST_P(CypherMainVisitorTest, VersionQuery) {
auto &ast_generator = *GetParam();
TestInvalidQuery("SHOW VERION", ast_generator);
TestInvalidQuery("SHOW VER", ast_generator);
TestInvalidQuery("SHOW VERSIONS", ast_generator);
ASSERT_NO_THROW(ast_generator.ParseQuery("SHOW VERSION"));
}
TEST_P(CypherMainVisitorTest, ConfigQuery) {
auto &ast_generator = *GetParam();
TestInvalidQuery("SHOW CF", ast_generator);
TestInvalidQuery("SHOW CFG", ast_generator);
TestInvalidQuery("SHOW CFGS", ast_generator);
TestInvalidQuery("SHOW CONF", ast_generator);
TestInvalidQuery("SHOW CONFIGS", ast_generator);
TestInvalidQuery("SHOW CONFIGURATION", ast_generator);
TestInvalidQuery("SHOW CONFIGURATIONS", ast_generator);
Query *query = ast_generator.ParseQuery("SHOW CONFIG");
auto *ptr = dynamic_cast<ShowConfigQuery *>(query);
ASSERT_TRUE(ptr != nullptr);
ASSERT_NO_THROW(ast_generator.ParseQuery("SHOW CONFIG"));
}
TEST_P(CypherMainVisitorTest, ForeachThrow) {
auto &ast_generator = *GetParam();
EXPECT_THROW(ast_generator.ParseQuery("FOREACH(i IN [1, 2] | UNWIND [1,2,3] AS j CREATE (n))"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("FOREACH(i IN [1, 2] CREATE (:Foo {prop : i}))"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("FOREACH(i IN [1, 2] | MATCH (n)"), SyntaxException);
EXPECT_THROW(ast_generator.ParseQuery("FOREACH(i IN x | MATCH (n)"), SyntaxException);
}
TEST_P(CypherMainVisitorTest, Foreach) {
auto &ast_generator = *GetParam();
// CREATE
{
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("FOREACH (age IN [1, 2, 3] | CREATE (m:Age {amount: age}))"));
ASSERT_TRUE(query);
ASSERT_TRUE(query->single_query_);
auto *single_query = query->single_query_;
ASSERT_EQ(single_query->clauses_.size(), 1U);
auto *foreach = dynamic_cast<Foreach *>(single_query->clauses_[0]);
ASSERT_TRUE(foreach);
ASSERT_TRUE(foreach->named_expression_);
EXPECT_EQ(foreach->named_expression_->name_, "age");
auto *expr = foreach->named_expression_->expression_;
ASSERT_TRUE(expr);
ASSERT_TRUE(dynamic_cast<ListLiteral *>(expr));
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 1);
ASSERT_TRUE(dynamic_cast<Create *>(clauses.front()));
}
// SET
{
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("FOREACH (i IN nodes(path) | SET i.checkpoint = true)"));
auto *foreach = dynamic_cast<Foreach *>(query->single_query_->clauses_[0]);
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 1);
ASSERT_TRUE(dynamic_cast<SetProperty *>(clauses.front()));
}
// REMOVE
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("FOREACH (i IN nodes(path) | REMOVE i.prop)"));
auto *foreach = dynamic_cast<Foreach *>(query->single_query_->clauses_[0]);
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 1);
ASSERT_TRUE(dynamic_cast<RemoveProperty *>(clauses.front()));
}
// MERGE
{
// merge works as create here
auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("FOREACH (i IN [1, 2, 3] | MERGE (n {no : i}))"));
auto *foreach = dynamic_cast<Foreach *>(query->single_query_->clauses_[0]);
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 1);
ASSERT_TRUE(dynamic_cast<Merge *>(clauses.front()));
}
// CYPHER DELETE
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("FOREACH (i IN nodes(path) | DETACH DELETE i)"));
auto *foreach = dynamic_cast<Foreach *>(query->single_query_->clauses_[0]);
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 1);
ASSERT_TRUE(dynamic_cast<Delete *>(clauses.front()));
}
// nested FOREACH
{
auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery(
"FOREACH (i IN nodes(path) | FOREACH (age IN i.list | CREATE (m:Age {amount: age})))"));
auto *foreach = dynamic_cast<Foreach *>(query->single_query_->clauses_[0]);
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 1);
ASSERT_TRUE(dynamic_cast<Foreach *>(clauses.front()));
}
// Multiple update clauses
{
auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("FOREACH (i IN nodes(path) | SET i.checkpoint = true REMOVE i.prop)"));
auto *foreach = dynamic_cast<Foreach *>(query->single_query_->clauses_[0]);
const auto &clauses = foreach->clauses_;
ASSERT_TRUE(clauses.size() == 2);
ASSERT_TRUE(dynamic_cast<SetProperty *>(clauses.front()));
ASSERT_TRUE(dynamic_cast<RemoveProperty *>(*++clauses.begin()));
}
}
TEST_P(CypherMainVisitorTest, ExistsThrow) {
auto &ast_generator = *GetParam();
TestInvalidQueryWithMessage<SyntaxException>("MATCH (n) WHERE exists(p=(n)-[]->()) RETURN n;", ast_generator,
"Identifiers are not supported in exists(...).");
}
TEST_P(CypherMainVisitorTest, Exists) {
auto &ast_generator = *GetParam();
{
const auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (n) WHERE exists((n)-[]->()) RETURN n;"));
const auto *match = dynamic_cast<Match *>(query->single_query_->clauses_[0]);
const auto *exists = dynamic_cast<Exists *>(match->where_->expression_);
ASSERT_TRUE(exists);
const auto pattern = exists->pattern_;
ASSERT_TRUE(pattern->atoms_.size() == 3);
const auto *node1 = dynamic_cast<NodeAtom *>(pattern->atoms_[0]);
const auto *edge = dynamic_cast<EdgeAtom *>(pattern->atoms_[1]);
const auto *node2 = dynamic_cast<NodeAtom *>(pattern->atoms_[2]);
ASSERT_TRUE(node1);
ASSERT_TRUE(edge);
ASSERT_TRUE(node2);
}
{
const auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (n) WHERE exists((n)-[]->()-[]->()) RETURN n;"));
const auto *match = dynamic_cast<Match *>(query->single_query_->clauses_[0]);
const auto *exists = dynamic_cast<Exists *>(match->where_->expression_);
ASSERT_TRUE(exists);
const auto pattern = exists->pattern_;
ASSERT_TRUE(pattern->atoms_.size() == 5);
const auto *node1 = dynamic_cast<NodeAtom *>(pattern->atoms_[0]);
const auto *edge = dynamic_cast<EdgeAtom *>(pattern->atoms_[1]);
const auto *node2 = dynamic_cast<NodeAtom *>(pattern->atoms_[2]);
const auto *edge2 = dynamic_cast<EdgeAtom *>(pattern->atoms_[3]);
const auto *node3 = dynamic_cast<NodeAtom *>(pattern->atoms_[4]);
ASSERT_TRUE(node1);
ASSERT_TRUE(edge);
ASSERT_TRUE(node2);
ASSERT_TRUE(edge2);
ASSERT_TRUE(node3);
}
{
const auto *query = dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (n) WHERE exists((n)) RETURN n;"));
const auto *match = dynamic_cast<Match *>(query->single_query_->clauses_[0]);
const auto *exists = dynamic_cast<Exists *>(match->where_->expression_);
ASSERT_TRUE(exists);
const auto pattern = exists->pattern_;
ASSERT_TRUE(pattern->atoms_.size() == 1);
const auto *node = dynamic_cast<NodeAtom *>(pattern->atoms_[0]);
ASSERT_TRUE(node);
}
}
TEST_P(CypherMainVisitorTest, CallSubqueryThrow) {
auto &ast_generator = *GetParam();
TestInvalidQueryWithMessage<SyntaxException>("MATCH (n) CALL { MATCH (m) RETURN m QUERY MEMORY UNLIMITED } RETURN n",
ast_generator, "Memory limit cannot be set on subqueries!");
}
TEST_P(CypherMainVisitorTest, CallSubquery) {
auto &ast_generator = *GetParam();
{
const auto *query =
dynamic_cast<CypherQuery *>(ast_generator.ParseQuery("MATCH (n) CALL { MATCH (m) RETURN m } RETURN n, m"));
const auto *call_subquery = dynamic_cast<CallSubquery *>(query->single_query_->clauses_[1]);
const auto *subquery = dynamic_cast<CypherQuery *>(call_subquery->cypher_query_);
ASSERT_TRUE(subquery);
const auto *match = dynamic_cast<Match *>(subquery->single_query_->clauses_[0]);
ASSERT_TRUE(match);
}
{
const auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("MATCH (n) CALL { MATCH (m) RETURN (m) UNION MATCH (m) RETURN m } RETURN n, m"));
const auto *call_subquery = dynamic_cast<CallSubquery *>(query->single_query_->clauses_[1]);
const auto *subquery = dynamic_cast<CypherQuery *>(call_subquery->cypher_query_);
ASSERT_TRUE(subquery);
const auto *match = dynamic_cast<Match *>(subquery->single_query_->clauses_[0]);
ASSERT_TRUE(match);
const auto unions = subquery->cypher_unions_;
ASSERT_TRUE(unions.size() == 1);
}
{
const auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("MATCH (n) CALL { MATCH (m) RETURN (m) UNION ALL MATCH (m) RETURN m } RETURN n, m"));
const auto *call_subquery = dynamic_cast<CallSubquery *>(query->single_query_->clauses_[1]);
const auto *subquery = dynamic_cast<CypherQuery *>(call_subquery->cypher_query_);
ASSERT_TRUE(subquery);
const auto *match = dynamic_cast<Match *>(subquery->single_query_->clauses_[0]);
ASSERT_TRUE(match);
const auto unions = subquery->cypher_unions_;
ASSERT_TRUE(unions.size() == 1);
}
{
const auto *query = dynamic_cast<CypherQuery *>(
ast_generator.ParseQuery("MATCH (n) CALL { MATCH (m) CALL { MATCH (o) RETURN o} RETURN m, o } RETURN n, m, o"));
const auto *call_subquery = dynamic_cast<CallSubquery *>(query->single_query_->clauses_[1]);
const auto *subquery = dynamic_cast<CypherQuery *>(call_subquery->cypher_query_);
ASSERT_TRUE(subquery);
const auto *match = dynamic_cast<Match *>(subquery->single_query_->clauses_[0]);
ASSERT_TRUE(match);
const auto *nested_subquery = dynamic_cast<CallSubquery *>(subquery->single_query_->clauses_[1]);
ASSERT_TRUE(nested_subquery);
const auto *nested_cypher = dynamic_cast<CypherQuery *>(nested_subquery->cypher_query_);
ASSERT_TRUE(nested_cypher);
const auto *nested_match = dynamic_cast<Match *>(nested_cypher->single_query_->clauses_[0]);
ASSERT_TRUE(nested_match);
}
}
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