/* * This file is open source software, licensed to you under the terms * of the Apache License, Version 2.0 (the "License"). See the NOTICE file * distributed with this work for additional information regarding copyright * ownership. You may not use this file except in compliance with the License. * * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. */ /* * Copyright 2020 ScyllaDB */ // Demonstration of seastar::with_file #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace seastar; constexpr size_t aligned_size = 4096; future<> verify_data_file(file& f, temporary_buffer& rbuf, const temporary_buffer& wbuf) { return f.dma_read(0, rbuf.get_write(), aligned_size).then([&rbuf, &wbuf] (size_t count) { assert(count == aligned_size); fmt::print(" verifying {} bytes\n", count); assert(!memcmp(rbuf.get(), wbuf.get(), aligned_size)); }); } future open_data_file(sstring meta_filename, temporary_buffer& rbuf) { fmt::print(" retrieving data filename from {}\n", meta_filename); return with_file(open_file_dma(meta_filename, open_flags::ro), [&rbuf] (file& f) { return f.dma_read(0, rbuf.get_write(), aligned_size).then([&rbuf] (size_t count) { assert(count == aligned_size); auto data_filename = sstring(rbuf.get()); fmt::print(" opening {}\n", data_filename); return open_file_dma(data_filename, open_flags::ro); }); }); } future<> demo_with_file() { fmt::print("Demonstrating with_file():\n"); return tmp_dir::do_with_thread([] (tmp_dir& t) { auto rnd = std::mt19937(std::random_device()()); auto dist = std::uniform_int_distribution(0, std::numeric_limits::max()); auto wbuf = temporary_buffer::aligned(aligned_size, aligned_size); sstring meta_filename = (t.get_path() / "meta_file").native(); sstring data_filename = (t.get_path() / "data_file").native(); // `with_file` is used to create/open `filename` just around the call to `dma_write` auto write_to_file = [] (const sstring filename, temporary_buffer& wbuf) { auto count = with_file(open_file_dma(filename, open_flags::rw | open_flags::create), [&wbuf] (file& f) { return f.dma_write(0, wbuf.get(), aligned_size); }).get0(); assert(count == aligned_size); }; // print the data_filename into the write buffer std::fill(wbuf.get_write(), wbuf.get_write() + aligned_size, 0); std::copy(data_filename.cbegin(), data_filename.cend(), wbuf.get_write()); // and write it to `meta_filename` fmt::print(" writing \"{}\" into {}\n", data_filename, meta_filename); write_to_file(meta_filename, wbuf); // now write some random data into data_filename fmt::print(" writing random data into {}\n", data_filename); std::generate(wbuf.get_write(), wbuf.get_write() + aligned_size, [&dist, &rnd] { return dist(rnd); }); write_to_file(data_filename, wbuf); // verify the data via meta_filename fmt::print(" verifying data...\n"); auto rbuf = temporary_buffer::aligned(aligned_size, aligned_size); with_file(open_data_file(meta_filename, rbuf), [&rbuf, &wbuf] (file& f) { return verify_data_file(f, rbuf, wbuf); }).get(); }); } future<> demo_with_file_close_on_failure() { fmt::print("\nDemonstrating with_file_close_on_failure():\n"); return tmp_dir::do_with_thread([] (tmp_dir& t) { auto rnd = std::mt19937(std::random_device()()); auto dist = std::uniform_int_distribution(0, std::numeric_limits::max()); auto wbuf = temporary_buffer::aligned(aligned_size, aligned_size); sstring meta_filename = (t.get_path() / "meta_file").native(); sstring data_filename = (t.get_path() / "data_file").native(); // with_file_close_on_failure will close the opened file only if // `make_file_output_stream` returns an error. Otherwise, in the error-free path, // the opened file is moved to `file_output_stream` that in-turn closes it // when the stream is closed. auto make_output_stream = [] (const sstring filename) { return with_file_close_on_failure(open_file_dma(std::move(filename), open_flags::rw | open_flags::create), [] (file f) { return make_file_output_stream(std::move(f), aligned_size); }); }; // writes the buffer one byte at a time, to demonstrate output stream auto write_to_stream = [] (output_stream& o, const temporary_buffer& wbuf) { return seastar::do_for_each(wbuf, [&o] (char c) { return o.write(&c, 1); }).finally([&o] { return o.close(); }); }; // print the data_filename into the write buffer std::fill(wbuf.get_write(), wbuf.get_write() + aligned_size, 0); std::copy(data_filename.cbegin(), data_filename.cend(), wbuf.get_write()); // and write it to `meta_filename` fmt::print(" writing \"{}\" into {}\n", data_filename, meta_filename); // with_file_close_on_failure will close the opened file only if // `make_file_output_stream` returns an error. Otherwise, in the error-free path, // the opened file is moved to `file_output_stream` that in-turn closes it // when the stream is closed. output_stream o = make_output_stream(meta_filename).get0(); write_to_stream(o, wbuf).get(); // now write some random data into data_filename fmt::print(" writing random data into {}\n", data_filename); std::generate(wbuf.get_write(), wbuf.get_write() + aligned_size, [&dist, &rnd] { return dist(rnd); }); o = make_output_stream(data_filename).get0(); write_to_stream(o, wbuf).get(); // verify the data via meta_filename fmt::print(" verifying data...\n"); auto rbuf = temporary_buffer::aligned(aligned_size, aligned_size); with_file(open_data_file(meta_filename, rbuf), [&rbuf, &wbuf] (file& f) { return verify_data_file(f, rbuf, wbuf); }).get(); }); } int main(int ac, char** av) { app_template app; return app.run(ac, av, [] { return demo_with_file().then([] { return demo_with_file_close_on_failure(); }); }); }