#pragma once //legacy code; no longer used #include #include #include #include namespace nall::Database { struct ODBC { struct Statement { Statement(const Statement& source) = delete; auto operator=(const Statement& source) -> Statement& = delete; Statement(SQLHANDLE statement) : _statement(statement) {} Statement(Statement&& source) { operator=(move(source)); } auto operator=(Statement&& source) -> Statement& { _statement = source._statement; _output = source._output; _values = move(source._values); source._statement = nullptr; source._output = 0; return *this; } auto columns() -> unsigned { SQLSMALLINT columns = 0; if(statement()) SQLNumResultCols(statement(), &columns); return columns; } auto integer(unsigned column) -> int64_t { if(auto value = _values(column)) return value.get(0); int64_t value = 0; SQLGetData(statement(), 1 + column, SQL_C_SBIGINT, &value, 0, nullptr); _values(column) = (int64_t)value; return value; } auto natural(unsigned column) -> uint64_t { if(auto value = _values(column)) return value.get(0); uint64_t value = 0; SQLGetData(statement(), 1 + column, SQL_C_UBIGINT, &value, 0, nullptr); _values(column) = (uint64_t)value; return value; } auto real(unsigned column) -> double { if(auto value = _values(column)) return value.get(0.0); double value = 0.0; SQLGetData(statement(), 1 + column, SQL_C_DOUBLE, &value, 0, nullptr); _values(column) = (double)value; return value; } auto text(unsigned column) -> string { if(auto value = _values(column)) return value.get({}); string value; value.resize(65535); SQLLEN size = 0; SQLGetData(statement(), 1 + column, SQL_C_CHAR, value.get(), value.size(), &size); value.resize(size); _values(column) = (string)value; return value; } auto data(unsigned column) -> vector { if(auto value = _values(column)) return value.get>({}); vector value; value.resize(65535); SQLLEN size = 0; SQLGetData(statement(), 1 + column, SQL_C_CHAR, value.data(), value.size(), &size); value.resize(size); _values(column) = (vector)value; return value; } auto integer() -> int64_t { return integer(_output++); } auto natural() -> uint64_t { return natural(_output++); } auto real() -> double { return real(_output++); } auto text() -> string { return text(_output++); } auto data() -> vector { return data(_output++); } protected: virtual auto statement() -> SQLHANDLE { return _statement; } SQLHANDLE _statement = nullptr; unsigned _output = 0; vector _values; //some ODBC drivers (eg MS-SQL) do not allow the same column to be read more than once }; struct Query : Statement { Query(const Query& source) = delete; auto operator=(const Query& source) -> Query& = delete; Query(SQLHANDLE statement) : Statement(statement) {} Query(Query&& source) : Statement(source._statement) { operator=(move(source)); } ~Query() { if(statement()) { SQLFreeHandle(SQL_HANDLE_STMT, _statement); _statement = nullptr; } } auto operator=(Query&& source) -> Query& { Statement::operator=(move(source)); _bindings = move(source._bindings); _result = source._result; _input = source._input; _stepped = source._stepped; source._result = SQL_SUCCESS; source._input = 0; source._stepped = false; return *this; } explicit operator bool() { //this is likely not the best way to test if the query has returned data ... //but I wasn't able to find an ODBC API for this seemingly simple task return statement() && success(); } //ODBC SQLBindParameter only holds pointers to data values //if the bound paramters go out of scope before the query is executed, binding would reference dangling pointers //so to work around this, we cache all parameters inside Query until the query is executed auto& bind(unsigned column, nullptr_t) { return _bindings.append({column, any{(nullptr_t)nullptr}}), *this; } auto& bind(unsigned column, int32_t value) { return _bindings.append({column, any{(int32_t)value}}), *this; } auto& bind(unsigned column, uint32_t value) { return _bindings.append({column, any{(uint32_t)value}}), *this; } auto& bind(unsigned column, int64_t value) { return _bindings.append({column, any{(int64_t)value}}), *this; } auto& bind(unsigned column, uint64_t value) { return _bindings.append({column, any{(uint64_t)value}}), *this; } auto& bind(unsigned column, double value) { return _bindings.append({column, any{(double)value}}), *this; } auto& bind(unsigned column, const string& value) { return _bindings.append({column, any{(string)value}}), *this; } auto& bind(unsigned column, const vector& value) { return _bindings.append({column, any{(vector)value}}), *this; } auto& bind(nullptr_t) { return bind(_input++, nullptr); } auto& bind(int32_t value) { return bind(_input++, value); } auto& bind(uint32_t value) { return bind(_input++, value); } auto& bind(int64_t value) { return bind(_input++, value); } auto& bind(uint64_t value) { return bind(_input++, value); } auto& bind(double value) { return bind(_input++, value); } auto& bind(const string& value) { return bind(_input++, value); } auto& bind(const vector& value) { return bind(_input++, value); } auto step() -> bool { if(!_stepped) { for(auto& binding : _bindings) { if(binding.value.is()) { SQLLEN length = SQL_NULL_DATA; SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_NUMERIC, SQL_NUMERIC, 0, 0, nullptr, 0, &length); } else if(binding.value.is()) { SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_SLONG, SQL_INTEGER, 0, 0, &binding.value.get(), 0, nullptr); } else if(binding.value.is()) { SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_ULONG, SQL_INTEGER, 0, 0, &binding.value.get(), 0, nullptr); } else if(binding.value.is()) { SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_SBIGINT, SQL_INTEGER, 0, 0, &binding.value.get(), 0, nullptr); } else if(binding.value.is()) { SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_UBIGINT, SQL_INTEGER, 0, 0, &binding.value.get(), 0, nullptr); } else if(binding.value.is()) { SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_DOUBLE, SQL_DOUBLE, 0, 0, &binding.value.get(), 0, nullptr); } else if(binding.value.is()) { auto& value = binding.value.get(); SQLLEN length = SQL_NTS; SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_CHAR, SQL_VARCHAR, value.size(), 0, (SQLPOINTER)value.data(), 0, &length); } else if(binding.value.is>()) { auto& value = binding.value.get>(); SQLLEN length = value.size(); SQLBindParameter(_statement, 1 + binding.column, SQL_PARAM_INPUT, SQL_C_CHAR, SQL_VARBINARY, value.size(), 0, (SQLPOINTER)value.data(), 0, &length); } } _stepped = true; _result = SQLExecute(_statement); if(!success()) return false; } _values.reset(); //clear previous row's cached read results _result = SQLFetch(_statement); _output = 0; return success(); } struct Iterator { Iterator(Query& query, bool finished) : query(query), finished(finished) {} auto operator*() -> Statement { return query._statement; } auto operator!=(const Iterator& source) const -> bool { return finished != source.finished; } auto operator++() -> Iterator& { finished = !query.step(); return *this; } protected: Query& query; bool finished = false; }; auto begin() -> Iterator { return Iterator(*this, !step()); } auto end() -> Iterator { return Iterator(*this, true); } private: auto success() const -> bool { return _result == SQL_SUCCESS || _result == SQL_SUCCESS_WITH_INFO; } auto statement() -> SQLHANDLE override { if(!_stepped) step(); return _statement; } struct Binding { unsigned column; any value; }; vector _bindings; SQLRETURN _result = SQL_SUCCESS; unsigned _input = 0; bool _stepped = false; }; ODBC() { _result = SQLAllocHandle(SQL_HANDLE_ENV, SQL_NULL_HANDLE, &_environment); if(!success()) return; SQLSetEnvAttr(_environment, SQL_ATTR_ODBC_VERSION, (void*)SQL_OV_ODBC3, 0); } ODBC(const string& database, const string& username, const string& password) : ODBC() { open(database, username, password); } ~ODBC() { if(_environment) { close(); SQLFreeHandle(SQL_HANDLE_ENV, _environment); _environment = nullptr; } } explicit operator bool() const { return _connection; } auto open(const string& database, const string& username, const string& password) -> bool { if(!_environment) return false; close(); _result = SQLAllocHandle(SQL_HANDLE_DBC, _environment, &_connection); if(!success()) return false; SQLSetConnectAttr(_connection, SQL_LOGIN_TIMEOUT, (SQLPOINTER)5, 0); _result = SQLConnectA(_connection, (SQLCHAR*)database.data(), SQL_NTS, (SQLCHAR*)username.data(), SQL_NTS, (SQLCHAR*)password.data(), SQL_NTS ); if(!success()) return close(), false; return true; } auto close() -> void { if(_connection) { SQLDisconnect(_connection); SQLFreeHandle(SQL_HANDLE_DBC, _connection); _connection = nullptr; } } template auto execute(const string& statement, P&&... p) -> Query { if(!_connection) return {nullptr}; SQLHANDLE _statement = nullptr; _result = SQLAllocHandle(SQL_HANDLE_STMT, _connection, &_statement); if(!success()) return {nullptr}; Query query{_statement}; _result = SQLPrepareA(_statement, (SQLCHAR*)statement.data(), SQL_NTS); if(!success()) return {nullptr}; bind(query, forward

(p)...); return query; } private: auto success() const -> bool { return _result == SQL_SUCCESS || _result == SQL_SUCCESS_WITH_INFO; } auto bind(Query&) -> void {} template auto bind(Query& query, const T& value, P&&... p) -> void { query.bind(value); bind(query, forward

(p)...); } SQLHANDLE _environment = nullptr; SQLHANDLE _connection = nullptr; SQLRETURN _result = SQL_SUCCESS; }; }