Mercurial > hg > orthanc-databases
view PostgreSQL/UnitTests/PostgreSQLTests.cpp @ 360:1d57fac91104 OrthancOdbc-1.1
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| author | Alain Mazy <am@osimis.io> |
|---|---|
| date | Thu, 28 Apr 2022 14:24:55 +0200 |
| parents | cc7af42d4f23 |
| children | 16aac0287485 |
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/** * Orthanc - A Lightweight, RESTful DICOM Store * Copyright (C) 2012-2016 Sebastien Jodogne, Medical Physics * Department, University Hospital of Liege, Belgium * Copyright (C) 2017-2021 Osimis S.A., Belgium * * This program is free software: you can redistribute it and/or * modify it under the terms of the GNU Affero General Public License * as published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. **/ #include <gtest/gtest.h> #if defined(_WIN32) // Fix redefinition of symbols on MinGW (these symbols are manually // defined both by PostgreSQL and Google Test) # undef S_IRGRP # undef S_IROTH # undef S_IRWXG # undef S_IRWXO # undef S_IWGRP # undef S_IWOTH # undef S_IXGRP # undef S_IXOTH #endif #include "../../Framework/Plugins/GlobalProperties.h" #include "../../Framework/PostgreSQL/PostgreSQLLargeObject.h" #include "../../Framework/PostgreSQL/PostgreSQLResult.h" #include "../../Framework/PostgreSQL/PostgreSQLTransaction.h" #include "../Plugins/PostgreSQLIndex.h" #include "../Plugins/PostgreSQLStorageArea.h" #include <Compatibility.h> // For std::unique_ptr<> #include <OrthancException.h> #include <boost/lexical_cast.hpp> using namespace OrthancDatabases; extern PostgreSQLParameters globalParameters_; static PostgreSQLDatabase* CreateTestDatabase() { std::unique_ptr<PostgreSQLDatabase> pg (new PostgreSQLDatabase(globalParameters_)); pg->Open(); pg->ClearAll(); return pg.release(); } static int64_t CountLargeObjects(PostgreSQLDatabase& db) { PostgreSQLTransaction transaction(db, TransactionType_ReadOnly); int64_t count; { // Count the number of large objects in the DB PostgreSQLStatement s(db, "SELECT COUNT(*) FROM pg_catalog.pg_largeobject"); PostgreSQLResult r(s); count = r.GetInteger64(0); } transaction.Commit(); return count; } TEST(PostgreSQL, Basic) { std::unique_ptr<PostgreSQLDatabase> pg(CreateTestDatabase()); ASSERT_FALSE(pg->DoesTableExist("Test")); ASSERT_FALSE(pg->DoesColumnExist("Test", "value")); ASSERT_FALSE(pg->DoesTableExist("TEST")); ASSERT_FALSE(pg->DoesTableExist("test")); pg->ExecuteMultiLines("CREATE TABLE Test(name INTEGER, value BIGINT)"); ASSERT_TRUE(pg->DoesTableExist("Test")); ASSERT_TRUE(pg->DoesTableExist("TEST")); ASSERT_TRUE(pg->DoesTableExist("test")); ASSERT_TRUE(pg->DoesColumnExist("Test", "Value")); ASSERT_TRUE(pg->DoesColumnExist("TEST", "VALUE")); ASSERT_TRUE(pg->DoesColumnExist("test", "value")); PostgreSQLStatement s(*pg, "INSERT INTO Test VALUES ($1,$2)"); s.DeclareInputInteger(0); s.DeclareInputInteger64(1); s.BindInteger(0, 43); s.BindNull(0); s.BindInteger(0, 42); s.BindInteger64(1, -4242); s.Run(); s.BindInteger(0, 43); s.BindNull(1); s.Run(); s.BindNull(0); s.BindInteger64(1, 4444); s.Run(); { PostgreSQLStatement t(*pg, "SELECT name, value FROM Test ORDER BY name"); PostgreSQLResult r(t); ASSERT_FALSE(r.IsDone()); ASSERT_FALSE(r.IsNull(0)); ASSERT_EQ(42, r.GetInteger(0)); ASSERT_FALSE(r.IsNull(1)); ASSERT_EQ(-4242, r.GetInteger64(1)); r.Next(); ASSERT_FALSE(r.IsDone()); ASSERT_FALSE(r.IsNull(0)); ASSERT_EQ(43, r.GetInteger(0)); ASSERT_TRUE(r.IsNull(1)); r.Next(); ASSERT_FALSE(r.IsDone()); ASSERT_TRUE(r.IsNull(0)); ASSERT_FALSE(r.IsNull(1)); ASSERT_EQ(4444, r.GetInteger64(1)); r.Next(); ASSERT_TRUE(r.IsDone()); } { PostgreSQLStatement t(*pg, "SELECT name, value FROM Test WHERE name=$1"); t.DeclareInputInteger(0); { t.BindInteger(0, 42); PostgreSQLResult r(t); ASSERT_FALSE(r.IsDone()); ASSERT_FALSE(r.IsNull(0)); ASSERT_EQ(42, r.GetInteger(0)); ASSERT_FALSE(r.IsNull(1)); ASSERT_EQ(-4242, r.GetInteger64(1)); r.Next(); ASSERT_TRUE(r.IsDone()); } { t.BindInteger(0, 40); PostgreSQLResult r(t); ASSERT_TRUE(r.IsDone()); } } } TEST(PostgreSQL, String) { std::unique_ptr<PostgreSQLDatabase> pg(CreateTestDatabase()); pg->ExecuteMultiLines("CREATE TABLE Test(name INTEGER, value VARCHAR(40))"); PostgreSQLStatement s(*pg, "INSERT INTO Test VALUES ($1,$2)"); s.DeclareInputInteger(0); s.DeclareInputString(1); s.BindInteger(0, 42); s.BindString(1, "Hello"); s.Run(); s.BindInteger(0, 43); s.BindNull(1); s.Run(); s.BindNull(0); s.BindString(1, ""); s.Run(); { PostgreSQLStatement t(*pg, "SELECT name, value FROM Test ORDER BY name"); PostgreSQLResult r(t); ASSERT_FALSE(r.IsDone()); ASSERT_FALSE(r.IsNull(0)); ASSERT_EQ(42, r.GetInteger(0)); ASSERT_FALSE(r.IsNull(1)); ASSERT_EQ("Hello", r.GetString(1)); r.Next(); ASSERT_FALSE(r.IsDone()); ASSERT_FALSE(r.IsNull(0)); ASSERT_EQ(43, r.GetInteger(0)); ASSERT_TRUE(r.IsNull(1)); r.Next(); ASSERT_FALSE(r.IsDone()); ASSERT_TRUE(r.IsNull(0)); ASSERT_FALSE(r.IsNull(1)); ASSERT_EQ("", r.GetString(1)); r.Next(); ASSERT_TRUE(r.IsDone()); } } TEST(PostgreSQL, Transaction) { std::unique_ptr<PostgreSQLDatabase> pg(CreateTestDatabase()); pg->ExecuteMultiLines("CREATE TABLE Test(name INTEGER, value INTEGER)"); { PostgreSQLStatement s(*pg, "INSERT INTO Test VALUES ($1,$2)"); s.DeclareInputInteger(0); s.DeclareInputInteger(1); s.BindInteger(0, 42); s.BindInteger(1, 4242); s.Run(); { PostgreSQLTransaction t(*pg, TransactionType_ReadOnly); s.BindInteger(0, 0); s.BindInteger(1, 1); // Failure, as INSERT in a read-only transaction ASSERT_THROW(s.Run(), Orthanc::OrthancException); } { PostgreSQLTransaction t(*pg, TransactionType_ReadWrite); s.BindInteger(0, 43); s.BindInteger(1, 4343); s.Run(); s.BindInteger(0, 44); s.BindInteger(1, 4444); s.Run(); PostgreSQLStatement u(*pg, "SELECT COUNT(*) FROM Test"); PostgreSQLResult r(u); ASSERT_EQ(3, r.GetInteger64(0)); // No commit } { // Implicit transaction PostgreSQLStatement u(*pg, "SELECT COUNT(*) FROM Test"); PostgreSQLResult r(u); ASSERT_EQ(1, r.GetInteger64(0)); // Just "1" because of implicit rollback } { PostgreSQLTransaction t(*pg, TransactionType_ReadWrite); s.BindInteger(0, 43); s.BindInteger(1, 4343); s.Run(); s.BindInteger(0, 44); s.BindInteger(1, 4444); s.Run(); { PostgreSQLStatement u(*pg, "SELECT COUNT(*) FROM Test"); PostgreSQLResult r(u); ASSERT_EQ(3, r.GetInteger64(0)); t.Commit(); ASSERT_THROW(t.Rollback(), Orthanc::OrthancException); ASSERT_THROW(t.Commit(), Orthanc::OrthancException); } } { PostgreSQLTransaction t(*pg, TransactionType_ReadOnly); PostgreSQLStatement u(*pg, "SELECT COUNT(*) FROM Test"); PostgreSQLResult r(u); ASSERT_EQ(3, r.GetInteger64(0)); } } } TEST(PostgreSQL, LargeObject) { std::unique_ptr<PostgreSQLDatabase> pg(CreateTestDatabase()); ASSERT_EQ(0, CountLargeObjects(*pg)); pg->ExecuteMultiLines("CREATE TABLE Test(name VARCHAR, value OID)"); // Automatically remove the large objects associated with the table pg->ExecuteMultiLines("CREATE RULE TestDelete AS ON DELETE TO Test DO SELECT lo_unlink(old.value);"); { PostgreSQLStatement s(*pg, "INSERT INTO Test VALUES ($1,$2)"); s.DeclareInputString(0); s.DeclareInputLargeObject(1); for (int i = 0; i < 10; i++) { PostgreSQLTransaction t(*pg, TransactionType_ReadWrite); std::string value = "Value " + boost::lexical_cast<std::string>(i * 2); PostgreSQLLargeObject obj(*pg, value); s.BindString(0, "Index " + boost::lexical_cast<std::string>(i)); s.BindLargeObject(1, obj); s.Run(); std::string tmp; PostgreSQLLargeObject::ReadWhole(tmp, *pg, obj.GetOid()); ASSERT_EQ(value, tmp); t.Commit(); } } ASSERT_EQ(10, CountLargeObjects(*pg)); { PostgreSQLTransaction t(*pg, TransactionType_ReadOnly); PostgreSQLStatement s(*pg, "SELECT * FROM Test ORDER BY name DESC"); PostgreSQLResult r(s); ASSERT_FALSE(r.IsDone()); ASSERT_FALSE(r.IsNull(0)); ASSERT_EQ("Index 9", r.GetString(0)); std::string data; r.GetLargeObjectContent(data, 1); ASSERT_EQ("Value 18", data); r.Next(); ASSERT_FALSE(r.IsDone()); //ASSERT_TRUE(r.IsString(0)); } { PostgreSQLTransaction t(*pg, TransactionType_ReadWrite); PostgreSQLStatement s(*pg, "DELETE FROM Test WHERE name='Index 9'"); s.Run(); t.Commit(); } { // Count the number of items in the DB PostgreSQLTransaction t(*pg, TransactionType_ReadOnly); PostgreSQLStatement s(*pg, "SELECT COUNT(*) FROM Test"); PostgreSQLResult r(s); ASSERT_EQ(9, r.GetInteger64(0)); } ASSERT_EQ(9, CountLargeObjects(*pg)); } TEST(PostgreSQL, StorageArea) { std::unique_ptr<PostgreSQLDatabase> database(PostgreSQLDatabase::CreateDatabaseConnection(globalParameters_)); PostgreSQLStorageArea storageArea(globalParameters_, true /* clear database */); { std::unique_ptr<OrthancDatabases::StorageBackend::IAccessor> accessor(storageArea.CreateAccessor()); ASSERT_EQ(0, CountLargeObjects(*database)); for (int i = 0; i < 10; i++) { std::string uuid = boost::lexical_cast<std::string>(i); std::string value = "Value " + boost::lexical_cast<std::string>(i * 2); accessor->Create(uuid, value.c_str(), value.size(), OrthancPluginContentType_Unknown); } std::string buffer; ASSERT_THROW(OrthancDatabases::StorageBackend::ReadWholeToString(buffer, *accessor, "nope", OrthancPluginContentType_Unknown), Orthanc::OrthancException); ASSERT_EQ(10, CountLargeObjects(*database)); accessor->Remove("5", OrthancPluginContentType_Unknown); ASSERT_EQ(9, CountLargeObjects(*database)); for (int i = 0; i < 10; i++) { std::string uuid = boost::lexical_cast<std::string>(i); std::string expected = "Value " + boost::lexical_cast<std::string>(i * 2); if (i == 5) { ASSERT_THROW(OrthancDatabases::StorageBackend::ReadWholeToString(buffer, *accessor, uuid, OrthancPluginContentType_Unknown), Orthanc::OrthancException); } else { OrthancDatabases::StorageBackend::ReadWholeToString(buffer, *accessor, uuid, OrthancPluginContentType_Unknown); ASSERT_EQ(expected, buffer); } } for (int i = 0; i < 10; i++) { accessor->Remove(boost::lexical_cast<std::string>(i), OrthancPluginContentType_Unknown); } ASSERT_EQ(0, CountLargeObjects(*database)); } } TEST(PostgreSQL, StorageReadRange) { std::unique_ptr<OrthancDatabases::PostgreSQLDatabase> database( OrthancDatabases::PostgreSQLDatabase::CreateDatabaseConnection(globalParameters_)); OrthancDatabases::PostgreSQLStorageArea storageArea(globalParameters_, true /* clear database */); { std::unique_ptr<OrthancDatabases::StorageBackend::IAccessor> accessor(storageArea.CreateAccessor()); ASSERT_EQ(0, CountLargeObjects(*database)); accessor->Create("uuid", "abcd\0\1\2\3\4\5", 10, OrthancPluginContentType_Unknown); ASSERT_EQ(1u, CountLargeObjects(*database)); } { std::unique_ptr<OrthancDatabases::StorageBackend::IAccessor> accessor(storageArea.CreateAccessor()); ASSERT_EQ(1u, CountLargeObjects(*database)); std::string s; OrthancDatabases::StorageBackend::ReadWholeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown); ASSERT_EQ(10u, s.size()); ASSERT_EQ('a', s[0]); ASSERT_EQ('d', s[3]); ASSERT_EQ('\0', s[4]); ASSERT_EQ('\5', s[9]); OrthancDatabases::StorageBackend::ReadRangeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown, 0, 0); ASSERT_TRUE(s.empty()); OrthancDatabases::StorageBackend::ReadRangeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown, 0, 1); ASSERT_EQ(1u, s.size()); ASSERT_EQ('a', s[0]); OrthancDatabases::StorageBackend::ReadRangeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown, 4, 1); ASSERT_EQ(1u, s.size()); ASSERT_EQ('\0', s[0]); OrthancDatabases::StorageBackend::ReadRangeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown, 9, 1); ASSERT_EQ(1u, s.size()); ASSERT_EQ('\5', s[0]); // Cannot read non-empty range after the end of the string. NB: // The behavior on range (10, 0) is different than in MySQL! ASSERT_THROW(OrthancDatabases::StorageBackend::ReadRangeToString( s, *accessor, "uuid", OrthancPluginContentType_Unknown, 10, 0), Orthanc::OrthancException); ASSERT_THROW(OrthancDatabases::StorageBackend::ReadRangeToString( s, *accessor, "uuid", OrthancPluginContentType_Unknown, 10, 1), Orthanc::OrthancException); OrthancDatabases::StorageBackend::ReadRangeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown, 0, 4); ASSERT_EQ(4u, s.size()); ASSERT_EQ('a', s[0]); ASSERT_EQ('b', s[1]); ASSERT_EQ('c', s[2]); ASSERT_EQ('d', s[3]); OrthancDatabases::StorageBackend::ReadRangeToString(s, *accessor, "uuid", OrthancPluginContentType_Unknown, 4, 6); ASSERT_EQ(6u, s.size()); ASSERT_EQ('\0', s[0]); ASSERT_EQ('\1', s[1]); ASSERT_EQ('\2', s[2]); ASSERT_EQ('\3', s[3]); ASSERT_EQ('\4', s[4]); ASSERT_EQ('\5', s[5]); ASSERT_THROW(OrthancDatabases::StorageBackend::ReadRangeToString( s, *accessor, "uuid", OrthancPluginContentType_Unknown, 4, 7), Orthanc::OrthancException); } } TEST(PostgreSQL, ImplicitTransaction) { std::unique_ptr<PostgreSQLDatabase> db(CreateTestDatabase()); ASSERT_FALSE(db->DoesTableExist("test")); ASSERT_FALSE(db->DoesTableExist("test2")); { std::unique_ptr<OrthancDatabases::ITransaction> t(db->CreateTransaction(TransactionType_ReadWrite)); ASSERT_FALSE(t->IsImplicit()); } { Query query("CREATE TABLE test(id INT)", false); std::unique_ptr<IPrecompiledStatement> s(db->Compile(query)); std::unique_ptr<ITransaction> t(db->CreateTransaction(TransactionType_Implicit)); ASSERT_TRUE(t->IsImplicit()); ASSERT_THROW(t->Commit(), Orthanc::OrthancException); ASSERT_THROW(t->Rollback(), Orthanc::OrthancException); Dictionary args; t->ExecuteWithoutResult(*s, args); ASSERT_THROW(t->Rollback(), Orthanc::OrthancException); t->Commit(); ASSERT_THROW(t->Commit(), Orthanc::OrthancException); } { // An implicit transaction does not need to be explicitely committed Query query("CREATE TABLE test2(id INT)", false); std::unique_ptr<IPrecompiledStatement> s(db->Compile(query)); std::unique_ptr<ITransaction> t(db->CreateTransaction(TransactionType_Implicit)); Dictionary args; t->ExecuteWithoutResult(*s, args); } ASSERT_TRUE(db->DoesTableExist("test")); ASSERT_TRUE(db->DoesTableExist("test2")); } #if ORTHANC_PLUGINS_HAS_DATABASE_CONSTRAINT == 1 TEST(PostgreSQLIndex, CreateInstance) { OrthancDatabases::PostgreSQLIndex db(NULL, globalParameters_); db.SetClearAll(true); std::unique_ptr<OrthancDatabases::DatabaseManager> manager(OrthancDatabases::IndexBackend::CreateSingleDatabaseManager(db)); std::string s; ASSERT_TRUE(db.LookupGlobalProperty(s, *manager, MISSING_SERVER_IDENTIFIER, Orthanc::GlobalProperty_DatabaseInternal1)); ASSERT_EQ("2", s); OrthancPluginCreateInstanceResult r1, r2; memset(&r1, 0, sizeof(r1)); db.CreateInstance(r1, *manager, "a", "b", "c", "d"); ASSERT_TRUE(r1.isNewInstance); ASSERT_TRUE(r1.isNewSeries); ASSERT_TRUE(r1.isNewStudy); ASSERT_TRUE(r1.isNewPatient); memset(&r2, 0, sizeof(r2)); db.CreateInstance(r2, *manager, "a", "b", "c", "d"); ASSERT_FALSE(r2.isNewInstance); ASSERT_EQ(r1.instanceId, r2.instanceId); // Breaking the hierarchy memset(&r2, 0, sizeof(r2)); ASSERT_THROW(db.CreateInstance(r2, *manager, "a", "e", "c", "f"), Orthanc::OrthancException); memset(&r2, 0, sizeof(r2)); db.CreateInstance(r2, *manager, "a", "b", "c", "e"); ASSERT_TRUE(r2.isNewInstance); ASSERT_FALSE(r2.isNewSeries); ASSERT_FALSE(r2.isNewStudy); ASSERT_FALSE(r2.isNewPatient); ASSERT_EQ(r1.patientId, r2.patientId); ASSERT_EQ(r1.studyId, r2.studyId); ASSERT_EQ(r1.seriesId, r2.seriesId); ASSERT_NE(r1.instanceId, r2.instanceId); memset(&r2, 0, sizeof(r2)); db.CreateInstance(r2, *manager, "a", "b", "f", "g"); ASSERT_TRUE(r2.isNewInstance); ASSERT_TRUE(r2.isNewSeries); ASSERT_FALSE(r2.isNewStudy); ASSERT_FALSE(r2.isNewPatient); ASSERT_EQ(r1.patientId, r2.patientId); ASSERT_EQ(r1.studyId, r2.studyId); ASSERT_NE(r1.seriesId, r2.seriesId); ASSERT_NE(r1.instanceId, r2.instanceId); memset(&r2, 0, sizeof(r2)); db.CreateInstance(r2, *manager, "a", "h", "i", "j"); ASSERT_TRUE(r2.isNewInstance); ASSERT_TRUE(r2.isNewSeries); ASSERT_TRUE(r2.isNewStudy); ASSERT_FALSE(r2.isNewPatient); ASSERT_EQ(r1.patientId, r2.patientId); ASSERT_NE(r1.studyId, r2.studyId); ASSERT_NE(r1.seriesId, r2.seriesId); ASSERT_NE(r1.instanceId, r2.instanceId); memset(&r2, 0, sizeof(r2)); db.CreateInstance(r2, *manager, "k", "l", "m", "n"); ASSERT_TRUE(r2.isNewInstance); ASSERT_TRUE(r2.isNewSeries); ASSERT_TRUE(r2.isNewStudy); ASSERT_TRUE(r2.isNewPatient); ASSERT_NE(r1.patientId, r2.patientId); ASSERT_NE(r1.studyId, r2.studyId); ASSERT_NE(r1.seriesId, r2.seriesId); ASSERT_NE(r1.instanceId, r2.instanceId); } #endif TEST(PostgreSQL, Lock2) { std::unique_ptr<PostgreSQLDatabase> db1(CreateTestDatabase()); ASSERT_FALSE(db1->ReleaseAdvisoryLock(43)); // lock counter = 0 ASSERT_TRUE(db1->AcquireAdvisoryLock(43)); // lock counter = 1 // OK, as this is the same connection ASSERT_TRUE(db1->AcquireAdvisoryLock(43)); // lock counter = 2 ASSERT_TRUE(db1->ReleaseAdvisoryLock(43)); // lock counter = 1 // Try and release twice the lock ASSERT_TRUE(db1->ReleaseAdvisoryLock(43)); // lock counter = 0 ASSERT_FALSE(db1->ReleaseAdvisoryLock(43)); // cannot unlock ASSERT_TRUE(db1->AcquireAdvisoryLock(43)); // lock counter = 1 { std::unique_ptr<PostgreSQLDatabase> db2(CreateTestDatabase()); // The "db1" is still actively locking ASSERT_FALSE(db2->AcquireAdvisoryLock(43)); // Release the "db1" lock ASSERT_TRUE(db1->ReleaseAdvisoryLock(43)); ASSERT_FALSE(db1->ReleaseAdvisoryLock(43)); // "db2" can now acquire the lock, but not "db1" ASSERT_TRUE(db2->AcquireAdvisoryLock(43)); ASSERT_FALSE(db1->AcquireAdvisoryLock(43)); } // "db2" is closed, "db1" can now acquire the lock ASSERT_TRUE(db1->AcquireAdvisoryLock(43)); }