rocksdb/utilities/env_librados.cc

1498 lines
36 KiB
C++
Raw Normal View History

Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
// Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved.
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
#include "rocksdb/utilities/env_librados.h"
#include "util/random.h"
#include <mutex>
#include <cstdlib>
namespace ROCKSDB_NAMESPACE {
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
/* GLOBAL DIFINE */
// #define DEBUG
#ifdef DEBUG
#include <cstdio>
#include <sys/syscall.h>
#include <unistd.h>
#define LOG_DEBUG(...) do{\
printf("[%ld:%s:%i:%s]", syscall(SYS_gettid), __FILE__, __LINE__, __FUNCTION__);\
printf(__VA_ARGS__);\
}while(0)
#else
#define LOG_DEBUG(...)
#endif
/* GLOBAL CONSTANT */
const char *default_db_name = "default_envlibrados_db";
const char *default_pool_name = "default_envlibrados_pool";
const char *default_config_path = "CEPH_CONFIG_PATH"; // the env variable name of ceph configure file
// maximum dir/file that can store in the fs
const int MAX_ITEMS_IN_FS = 1 << 30;
// root dir tag
const std::string ROOT_DIR_KEY = "/";
const std::string DIR_ID_VALUE = "<DIR>";
/**
* @brief convert error code to status
* @details Convert internal linux error code to Status
*
* @param r [description]
* @return [description]
*/
Status err_to_status(int r)
{
switch (r) {
case 0:
return Status::OK();
case -ENOENT:
return Status::IOError();
case -ENODATA:
case -ENOTDIR:
return Status::NotFound(Status::kNone);
case -EINVAL:
return Status::InvalidArgument(Status::kNone);
case -EIO:
return Status::IOError(Status::kNone);
default:
// FIXME :(
assert(0 == "unrecognized error code");
return Status::NotSupported(Status::kNone);
}
}
/**
* @brief split file path into dir path and file name
* @details
* Because rocksdb only need a 2-level structure (dir/file), all input path will be shortened to dir/file format
* For example:
* b/c => dir '/b', file 'c'
* /a/b/c => dir '/b', file 'c'
*
* @param fn [description]
* @param dir [description]
* @param file [description]
*/
void split(const std::string &fn, std::string *dir, std::string *file) {
LOG_DEBUG("[IN]%s\n", fn.c_str());
int pos = fn.size() - 1;
while ('/' == fn[pos]) --pos;
size_t fstart = fn.rfind('/', pos);
*file = fn.substr(fstart + 1, pos - fstart);
pos = fstart;
while (pos >= 0 && '/' == fn[pos]) --pos;
if (pos < 0) {
*dir = "/";
} else {
size_t dstart = fn.rfind('/', pos);
*dir = fn.substr(dstart + 1, pos - dstart);
*dir = std::string("/") + *dir;
}
LOG_DEBUG("[OUT]%s | %s\n", dir->c_str(), file->c_str());
}
// A file abstraction for reading sequentially through a file
class LibradosSequentialFile : public SequentialFile {
librados::IoCtx * _io_ctx;
std::string _fid;
std::string _hint;
int _offset;
public:
LibradosSequentialFile(librados::IoCtx * io_ctx, std::string fid, std::string hint):
_io_ctx(io_ctx), _fid(fid), _hint(hint), _offset(0) {}
~LibradosSequentialFile() {}
/**
* @brief read file
* @details
* Read up to "n" bytes from the file. "scratch[0..n-1]" may be
* written by this routine. Sets "*result" to the data that was
* read (including if fewer than "n" bytes were successfully read).
* May set "*result" to point at data in "scratch[0..n-1]", so
* "scratch[0..n-1]" must be live when "*result" is used.
* If an error was encountered, returns a non-OK status.
*
* REQUIRES: External synchronization
*
* @param n [description]
* @param result [description]
* @param scratch [description]
* @return [description]
*/
Status Read(size_t n, Slice* result, char* scratch) {
LOG_DEBUG("[IN]%i\n", (int)n);
librados::bufferlist buffer;
Status s;
int r = _io_ctx->read(_fid, buffer, n, _offset);
if (r >= 0) {
buffer.begin().copy(r, scratch);
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
*result = Slice(scratch, r);
_offset += r;
s = Status::OK();
} else {
s = err_to_status(r);
if (s == Status::IOError()) {
*result = Slice();
s = Status::OK();
}
}
LOG_DEBUG("[OUT]%s, %i, %s\n", s.ToString().c_str(), (int)r, buffer.c_str());
return s;
}
/**
* @brief skip "n" bytes from the file
* @details
* Skip "n" bytes from the file. This is guaranteed to be no
* slower that reading the same data, but may be faster.
*
* If end of file is reached, skipping will stop at the end of the
* file, and Skip will return OK.
*
* REQUIRES: External synchronization
*
* @param n [description]
* @return [description]
*/
Status Skip(uint64_t n) {
_offset += n;
return Status::OK();
}
/**
* @brief noop
* @details
* rocksdb has it's own caching capabilities that we should be able to use,
* without relying on a cache here. This can safely be a no-op.
*
* @param offset [description]
* @param length [description]
*
* @return [description]
*/
Status InvalidateCache(size_t offset, size_t length) {
return Status::OK();
}
};
// A file abstraction for randomly reading the contents of a file.
class LibradosRandomAccessFile : public RandomAccessFile {
librados::IoCtx * _io_ctx;
std::string _fid;
std::string _hint;
public:
LibradosRandomAccessFile(librados::IoCtx * io_ctx, std::string fid, std::string hint):
_io_ctx(io_ctx), _fid(fid), _hint(hint) {}
~LibradosRandomAccessFile() {}
/**
* @brief read file
* @details similar to LibradosSequentialFile::Read
*
* @param offset [description]
* @param n [description]
* @param result [description]
* @param scratch [description]
* @return [description]
*/
Status Read(uint64_t offset, size_t n, Slice* result,
char* scratch) const {
LOG_DEBUG("[IN]%i\n", (int)n);
librados::bufferlist buffer;
Status s;
int r = _io_ctx->read(_fid, buffer, n, offset);
if (r >= 0) {
buffer.begin().copy(r, scratch);
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
*result = Slice(scratch, r);
s = Status::OK();
} else {
s = err_to_status(r);
if (s == Status::IOError()) {
*result = Slice();
s = Status::OK();
}
}
LOG_DEBUG("[OUT]%s, %i, %s\n", s.ToString().c_str(), (int)r, buffer.c_str());
return s;
}
/**
* @brief [brief description]
* @details Get unique id for each file and guarantee this id is different for each file
*
* @param id [description]
* @param max_size max size of id, it shoud be larger than 16
*
* @return [description]
*/
size_t GetUniqueId(char* id, size_t max_size) const {
// All fid has the same db_id prefix, so we need to ignore db_id prefix
size_t s = std::min(max_size, _fid.size());
strncpy(id, _fid.c_str() + (_fid.size() - s), s);
id[s - 1] = '\0';
return s;
};
//enum AccessPattern { NORMAL, RANDOM, SEQUENTIAL, WILLNEED, DONTNEED };
void Hint(AccessPattern pattern) {
/* Do nothing */
}
/**
* @brief noop
* @details [long description]
*
* @param offset [description]
* @param length [description]
*
* @return [description]
*/
Status InvalidateCache(size_t offset, size_t length) {
return Status::OK();
}
};
// A file abstraction for sequential writing. The implementation
// must provide buffering since callers may append small fragments
// at a time to the file.
class LibradosWritableFile : public WritableFile {
librados::IoCtx * _io_ctx;
std::string _fid;
std::string _hint;
const EnvLibrados * const _env;
std::mutex _mutex; // used to protect modification of all following variables
librados::bufferlist _buffer; // write buffer
uint64_t _buffer_size; // write buffer size
uint64_t _file_size; // this file size doesn't include buffer size
/**
* @brief assuming caller holds lock
* @details [long description]
* @return [description]
*/
int _SyncLocked() {
// 1. sync append data to RADOS
int r = _io_ctx->append(_fid, _buffer, _buffer_size);
assert(r >= 0);
// 2. update local variables
if (0 == r) {
_buffer.clear();
_file_size += _buffer_size;
_buffer_size = 0;
}
return r;
}
Optionally wait on bytes_per_sync to smooth I/O (#5183) Summary: The existing implementation does not guarantee bytes reach disk every `bytes_per_sync` when writing SST files, or every `wal_bytes_per_sync` when writing WALs. This can cause confusing behavior for users who enable this feature to avoid large syncs during flush and compaction, but then end up hitting them anyways. My understanding of the existing behavior is we used `sync_file_range` with `SYNC_FILE_RANGE_WRITE` to submit ranges for async writeback, such that we could continue processing the next range of bytes while that I/O is happening. I believe we can preserve that benefit while also limiting how far the processing can get ahead of the I/O, which prevents huge syncs from happening when the file finishes. Consider this `sync_file_range` usage: `sync_file_range(fd_, 0, static_cast<off_t>(offset + nbytes), SYNC_FILE_RANGE_WAIT_BEFORE | SYNC_FILE_RANGE_WRITE)`. Expanding the range to start at 0 and adding the `SYNC_FILE_RANGE_WAIT_BEFORE` flag causes any pending writeback (like from a previous call to `sync_file_range`) to finish before it proceeds to submit the latest `nbytes` for writeback. The latest `nbytes` are still written back asynchronously, unless processing exceeds I/O speed, in which case the following `sync_file_range` will need to wait on it. There is a second change in this PR to use `fdatasync` when `sync_file_range` is unavailable (determined statically) or has some known problem with the underlying filesystem (determined dynamically). The above two changes only apply when the user enables a new option, `strict_bytes_per_sync`. Pull Request resolved: https://github.com/facebook/rocksdb/pull/5183 Differential Revision: D14953553 Pulled By: siying fbshipit-source-id: 445c3862e019fb7b470f9c7f314fc231b62706e9
2019-04-22 18:48:45 +00:00
public:
LibradosWritableFile(librados::IoCtx* io_ctx, std::string fid,
std::string hint, const EnvLibrados* const env,
const EnvOptions& options)
: WritableFile(options),
_io_ctx(io_ctx),
_fid(fid),
_hint(hint),
_env(env),
_buffer(),
_buffer_size(0),
_file_size(0) {
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
int ret = _io_ctx->stat(_fid, &_file_size, nullptr);
// if file not exist
if (ret < 0) {
_file_size = 0;
}
}
~LibradosWritableFile() {
// sync before closeing writable file
Sync();
}
/**
* @brief append data to file
* @details
* Append will save all written data in buffer util buffer size
* reaches buffer max size. Then, it will write buffer into rados
*
* @param data [description]
* @return [description]
*/
Status Append(const Slice& data) {
// append buffer
LOG_DEBUG("[IN] %i | %s\n", (int)data.size(), data.data());
int r = 0;
std::lock_guard<std::mutex> lock(_mutex);
_buffer.append(data.data(), data.size());
_buffer_size += data.size();
if (_buffer_size > _env->_write_buffer_size) {
r = _SyncLocked();
}
LOG_DEBUG("[OUT] %i\n", r);
return err_to_status(r);
}
/**
* @brief not supported
* @details [long description]
* @return [description]
*/
Status PositionedAppend(
const Slice& /* data */,
uint64_t /* offset */) {
return Status::NotSupported();
}
/**
* @brief truncate file to assigned size
* @details [long description]
*
* @param size [description]
* @return [description]
*/
Status Truncate(uint64_t size) {
LOG_DEBUG("[IN]%lld|%lld|%lld\n", (long long)size, (long long)_file_size, (long long)_buffer_size);
int r = 0;
std::lock_guard<std::mutex> lock(_mutex);
if (_file_size > size) {
r = _io_ctx->trunc(_fid, size);
if (r == 0) {
_buffer.clear();
_buffer_size = 0;
_file_size = size;
}
} else if (_file_size == size) {
_buffer.clear();
_buffer_size = 0;
} else {
librados::bufferlist tmp;
tmp.claim(_buffer);
_buffer.substr_of(tmp, 0, size - _file_size);
_buffer_size = size - _file_size;
}
LOG_DEBUG("[OUT] %i\n", r);
return err_to_status(r);
}
/**
* @brief close file
* @details [long description]
* @return [description]
*/
Status Close() {
LOG_DEBUG("%s | %lld | %lld\n", _hint.c_str(), (long long)_buffer_size, (long long)_file_size);
return Sync();
}
/**
* @brief flush file,
* @details initiate an aio write and not wait
*
* @return [description]
*/
Status Flush() {
librados::AioCompletion *write_completion = librados::Rados::aio_create_completion();
int r = 0;
std::lock_guard<std::mutex> lock(_mutex);
r = _io_ctx->aio_append(_fid, write_completion, _buffer, _buffer_size);
if (0 == r) {
_file_size += _buffer_size;
_buffer.clear();
_buffer_size = 0;
}
write_completion->release();
return err_to_status(r);
}
/**
* @brief write buffer data to rados
* @details initiate an aio write and wait for result
* @return [description]
*/
Status Sync() { // sync data
int r = 0;
std::lock_guard<std::mutex> lock(_mutex);
if (_buffer_size > 0) {
r = _SyncLocked();
}
return err_to_status(r);
}
/**
* @brief [brief description]
* @details [long description]
* @return true if Sync() and Fsync() are safe to call concurrently with Append()and Flush().
*/
bool IsSyncThreadSafe() const {
return true;
}
/**
* @brief Indicates the upper layers if the current WritableFile implementation uses direct IO.
* @details [long description]
* @return [description]
*/
bool use_direct_io() const {
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
return false;
}
/**
* @brief Get file size
* @details
* This API will use cached file_size.
* @return [description]
*/
uint64_t GetFileSize() {
LOG_DEBUG("%lld|%lld\n", (long long)_buffer_size, (long long)_file_size);
std::lock_guard<std::mutex> lock(_mutex);
int file_size = _file_size + _buffer_size;
return file_size;
}
/**
* @brief For documentation, refer to RandomAccessFile::GetUniqueId()
* @details [long description]
*
* @param id [description]
* @param max_size [description]
*
* @return [description]
*/
size_t GetUniqueId(char* id, size_t max_size) const {
// All fid has the same db_id prefix, so we need to ignore db_id prefix
size_t s = std::min(max_size, _fid.size());
strncpy(id, _fid.c_str() + (_fid.size() - s), s);
id[s - 1] = '\0';
return s;
}
/**
* @brief noop
* @details [long description]
*
* @param offset [description]
* @param length [description]
*
* @return [description]
*/
Status InvalidateCache(size_t offset, size_t length) {
return Status::OK();
}
using WritableFile::RangeSync;
/**
* @brief No RangeSync support, just call Sync()
* @details [long description]
*
* @param offset [description]
* @param nbytes [description]
*
* @return [description]
*/
Status RangeSync(off_t offset, off_t nbytes) {
return Sync();
}
protected:
using WritableFile::Allocate;
/**
* @brief noop
* @details [long description]
*
* @param offset [description]
* @param len [description]
*
* @return [description]
*/
Status Allocate(off_t offset, off_t len) {
return Status::OK();
}
};
// Directory object represents collection of files and implements
// filesystem operations that can be executed on directories.
class LibradosDirectory : public Directory {
librados::IoCtx * _io_ctx;
std::string _fid;
public:
explicit LibradosDirectory(librados::IoCtx * io_ctx, std::string fid):
_io_ctx(io_ctx), _fid(fid) {}
// Fsync directory. Can be called concurrently from multiple threads.
Status Fsync() {
return Status::OK();
}
};
// Identifies a locked file.
// This is exclusive lock and can't nested lock by same thread
class LibradosFileLock : public FileLock {
librados::IoCtx * _io_ctx;
const std::string _obj_name;
const std::string _lock_name;
const std::string _cookie;
int lock_state;
public:
LibradosFileLock(
librados::IoCtx * io_ctx,
const std::string obj_name):
_io_ctx(io_ctx),
_obj_name(obj_name),
_lock_name("lock_name"),
_cookie("cookie") {
// TODO: the lock will never expire. It may cause problem if the process crash or abnormally exit.
while (!_io_ctx->lock_exclusive(
_obj_name,
_lock_name,
_cookie,
"description", nullptr, 0));
}
~LibradosFileLock() {
_io_ctx->unlock(_obj_name, _lock_name, _cookie);
}
};
// --------------------
// --- EnvLibrados ----
// --------------------
/**
* @brief EnvLibrados ctor
* @details [long description]
*
* @param db_name unique database name
* @param config_path the configure file path for rados
*/
EnvLibrados::EnvLibrados(const std::string& db_name,
const std::string& config_path,
const std::string& db_pool)
: EnvLibrados("client.admin",
"ceph",
0,
db_name,
config_path,
db_pool,
"/wal",
db_pool,
1 << 20) {}
/**
* @brief EnvLibrados ctor
* @details [long description]
*
* @param client_name first 3 parameters is for RADOS client init
* @param cluster_name
* @param flags
* @param db_name unique database name, used as db_id key
* @param config_path the configure file path for rados
* @param db_pool the pool for db data
* @param wal_pool the pool for WAL data
* @param write_buffer_size WritableFile buffer max size
*/
EnvLibrados::EnvLibrados(const std::string& client_name,
const std::string& cluster_name,
const uint64_t flags,
const std::string& db_name,
const std::string& config_path,
const std::string& db_pool,
const std::string& wal_dir,
const std::string& wal_pool,
const uint64_t write_buffer_size)
: EnvWrapper(Env::Default()),
_client_name(client_name),
_cluster_name(cluster_name),
_flags(flags),
_db_name(db_name),
_config_path(config_path),
_db_pool_name(db_pool),
_wal_dir(wal_dir),
_wal_pool_name(wal_pool),
_write_buffer_size(write_buffer_size) {
int ret = 0;
// 1. create a Rados object and initialize it
ret = _rados.init2(_client_name.c_str(), _cluster_name.c_str(), _flags); // just use the client.admin keyring
if (ret < 0) { // let's handle any error that might have come back
std::cerr << "couldn't initialize rados! error " << ret << std::endl;
ret = EXIT_FAILURE;
goto out;
}
// 2. read configure file
ret = _rados.conf_read_file(_config_path.c_str());
if (ret < 0) {
// This could fail if the config file is malformed, but it'd be hard.
std::cerr << "failed to parse config file " << _config_path
<< "! error" << ret << std::endl;
ret = EXIT_FAILURE;
goto out;
}
// 3. we actually connect to the cluster
ret = _rados.connect();
if (ret < 0) {
std::cerr << "couldn't connect to cluster! error " << ret << std::endl;
ret = EXIT_FAILURE;
goto out;
}
// 4. create db_pool if not exist
ret = _rados.pool_create(_db_pool_name.c_str());
if (ret < 0 && ret != -EEXIST && ret != -EPERM) {
std::cerr << "couldn't create pool! error " << ret << std::endl;
goto out;
}
// 5. create db_pool_ioctx
ret = _rados.ioctx_create(_db_pool_name.c_str(), _db_pool_ioctx);
if (ret < 0) {
std::cerr << "couldn't set up ioctx! error " << ret << std::endl;
ret = EXIT_FAILURE;
goto out;
}
// 6. create wal_pool if not exist
ret = _rados.pool_create(_wal_pool_name.c_str());
if (ret < 0 && ret != -EEXIST && ret != -EPERM) {
std::cerr << "couldn't create pool! error " << ret << std::endl;
goto out;
}
// 7. create wal_pool_ioctx
ret = _rados.ioctx_create(_wal_pool_name.c_str(), _wal_pool_ioctx);
if (ret < 0) {
std::cerr << "couldn't set up ioctx! error " << ret << std::endl;
ret = EXIT_FAILURE;
goto out;
}
// 8. add root dir
_AddFid(ROOT_DIR_KEY, DIR_ID_VALUE);
out:
LOG_DEBUG("rados connect result code : %i\n", ret);
}
/****************************************************
private functions to handle fid operation.
Dir also have fid, but the value is DIR_ID_VALUE
****************************************************/
/**
* @brief generate a new fid
* @details [long description]
* @return [description]
*/
std::string EnvLibrados::_CreateFid() {
return _db_name + "." + GenerateUniqueId();
}
/**
* @brief get fid
* @details [long description]
*
* @param fname [description]
* @param fid [description]
*
* @return
* Status::OK()
* Status::NotFound()
*/
Status EnvLibrados::_GetFid(
const std::string &fname,
std::string& fid) {
std::set<std::string> keys;
std::map<std::string, librados::bufferlist> kvs;
keys.insert(fname);
int r = _db_pool_ioctx.omap_get_vals_by_keys(_db_name, keys, &kvs);
if (0 == r && 0 == kvs.size()) {
return Status::NotFound();
} else if (0 == r && 0 != kvs.size()) {
fid.assign(kvs[fname].c_str(), kvs[fname].length());
return Status::OK();
} else {
return err_to_status(r);
}
}
/**
* @brief rename fid
* @details Only modify object in rados once,
* so this rename operation is atomic in term of rados
*
* @param old_fname [description]
* @param new_fname [description]
*
* @return [description]
*/
Status EnvLibrados::_RenameFid(const std::string& old_fname,
const std::string& new_fname) {
std::string fid;
Status s = _GetFid(old_fname, fid);
if (Status::OK() != s) {
return s;
}
librados::bufferlist bl;
std::set<std::string> keys;
std::map<std::string, librados::bufferlist> kvs;
librados::ObjectWriteOperation o;
bl.append(fid);
keys.insert(old_fname);
kvs[new_fname] = bl;
o.omap_rm_keys(keys);
o.omap_set(kvs);
int r = _db_pool_ioctx.operate(_db_name, &o);
return err_to_status(r);
}
/**
* @brief add <file path, fid> to metadata object. It may overwrite exist key.
* @details [long description]
*
* @param fname [description]
* @param fid [description]
*
* @return [description]
*/
Status EnvLibrados::_AddFid(
const std::string& fname,
const std::string& fid) {
std::map<std::string, librados::bufferlist> kvs;
librados::bufferlist value;
value.append(fid);
kvs[fname] = value;
int r = _db_pool_ioctx.omap_set(_db_name, kvs);
return err_to_status(r);
}
/**
* @brief return subfile names of dir.
* @details
* RocksDB has a 2-level structure, so all keys
* that have dir as prefix are subfiles of dir.
* So we can just return these files' name.
*
* @param dir [description]
* @param result [description]
*
* @return [description]
*/
Status EnvLibrados::_GetSubFnames(
const std::string& dir,
std::vector<std::string> * result
) {
std::string start_after(dir);
std::string filter_prefix(dir);
std::map<std::string, librados::bufferlist> kvs;
_db_pool_ioctx.omap_get_vals(_db_name,
start_after, filter_prefix,
MAX_ITEMS_IN_FS, &kvs);
result->clear();
for (auto i = kvs.begin(); i != kvs.end(); i++) {
result->push_back(i->first.substr(dir.size() + 1));
}
return Status::OK();
}
/**
* @brief delete key fname from metadata object
* @details [long description]
*
* @param fname [description]
* @return [description]
*/
Status EnvLibrados::_DelFid(
const std::string& fname) {
std::set<std::string> keys;
keys.insert(fname);
int r = _db_pool_ioctx.omap_rm_keys(_db_name, keys);
return err_to_status(r);
}
/**
* @brief get match IoCtx from _prefix_pool_map
* @details [long description]
*
* @param prefix [description]
* @return [description]
*
*/
librados::IoCtx* EnvLibrados::_GetIoctx(const std::string& fpath) {
auto is_prefix = [](const std::string & s1, const std::string & s2) {
auto it1 = s1.begin(), it2 = s2.begin();
while (it1 != s1.end() && it2 != s2.end() && *it1 == *it2) ++it1, ++it2;
return it1 == s1.end();
};
if (is_prefix(_wal_dir, fpath)) {
return &_wal_pool_ioctx;
} else {
return &_db_pool_ioctx;
}
}
/************************************************************
public functions
************************************************************/
/**
* @brief generate unique id
* @details Combine system time and random number.
* @return [description]
*/
std::string EnvLibrados::GenerateUniqueId() {
Random64 r(time(nullptr));
uint64_t random_uuid_portion =
r.Uniform(std::numeric_limits<uint64_t>::max());
uint64_t nanos_uuid_portion = NowNanos();
char uuid2[200];
snprintf(uuid2,
200,
"%16lx-%16lx",
(unsigned long)nanos_uuid_portion,
(unsigned long)random_uuid_portion);
return uuid2;
}
/**
* @brief create a new sequential read file handler
* @details it will check the existence of fname
*
* @param fname [description]
* @param result [description]
* @param options [description]
* @return [description]
*/
Status EnvLibrados::NewSequentialFile(
const std::string& fname,
std::unique_ptr<SequentialFile>* result,
const EnvOptions& options)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string dir, file, fid;
split(fname, &dir, &file);
Status s;
std::string fpath = dir + "/" + file;
do {
s = _GetFid(dir, fid);
if (!s.ok() || fid != DIR_ID_VALUE) {
if (fid != DIR_ID_VALUE) s = Status::IOError();
break;
}
s = _GetFid(fpath, fid);
if (Status::NotFound() == s) {
s = Status::IOError();
errno = ENOENT;
break;
}
result->reset(new LibradosSequentialFile(_GetIoctx(fpath), fid, fpath));
s = Status::OK();
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief create a new random access file handler
* @details it will check the existence of fname
*
* @param fname [description]
* @param result [description]
* @param options [description]
* @return [description]
*/
Status EnvLibrados::NewRandomAccessFile(
const std::string& fname,
std::unique_ptr<RandomAccessFile>* result,
const EnvOptions& options)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string dir, file, fid;
split(fname, &dir, &file);
Status s;
std::string fpath = dir + "/" + file;
do {
s = _GetFid(dir, fid);
if (!s.ok() || fid != DIR_ID_VALUE) {
s = Status::IOError();
break;
}
s = _GetFid(fpath, fid);
if (Status::NotFound() == s) {
s = Status::IOError();
errno = ENOENT;
break;
}
result->reset(new LibradosRandomAccessFile(_GetIoctx(fpath), fid, fpath));
s = Status::OK();
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief create a new write file handler
* @details it will check the existence of fname
*
* @param fname [description]
* @param result [description]
* @param options [description]
* @return [description]
*/
Status EnvLibrados::NewWritableFile(
const std::string& fname,
std::unique_ptr<WritableFile>* result,
const EnvOptions& options)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string dir, file, fid;
split(fname, &dir, &file);
Status s;
std::string fpath = dir + "/" + file;
do {
// 1. check if dir exist
s = _GetFid(dir, fid);
if (!s.ok()) {
break;
}
if (fid != DIR_ID_VALUE) {
s = Status::IOError();
break;
}
// 2. check if file exist.
// 2.1 exist, use it
// 2.2 not exist, create it
s = _GetFid(fpath, fid);
if (Status::NotFound() == s) {
fid = _CreateFid();
_AddFid(fpath, fid);
}
Optionally wait on bytes_per_sync to smooth I/O (#5183) Summary: The existing implementation does not guarantee bytes reach disk every `bytes_per_sync` when writing SST files, or every `wal_bytes_per_sync` when writing WALs. This can cause confusing behavior for users who enable this feature to avoid large syncs during flush and compaction, but then end up hitting them anyways. My understanding of the existing behavior is we used `sync_file_range` with `SYNC_FILE_RANGE_WRITE` to submit ranges for async writeback, such that we could continue processing the next range of bytes while that I/O is happening. I believe we can preserve that benefit while also limiting how far the processing can get ahead of the I/O, which prevents huge syncs from happening when the file finishes. Consider this `sync_file_range` usage: `sync_file_range(fd_, 0, static_cast<off_t>(offset + nbytes), SYNC_FILE_RANGE_WAIT_BEFORE | SYNC_FILE_RANGE_WRITE)`. Expanding the range to start at 0 and adding the `SYNC_FILE_RANGE_WAIT_BEFORE` flag causes any pending writeback (like from a previous call to `sync_file_range`) to finish before it proceeds to submit the latest `nbytes` for writeback. The latest `nbytes` are still written back asynchronously, unless processing exceeds I/O speed, in which case the following `sync_file_range` will need to wait on it. There is a second change in this PR to use `fdatasync` when `sync_file_range` is unavailable (determined statically) or has some known problem with the underlying filesystem (determined dynamically). The above two changes only apply when the user enables a new option, `strict_bytes_per_sync`. Pull Request resolved: https://github.com/facebook/rocksdb/pull/5183 Differential Revision: D14953553 Pulled By: siying fbshipit-source-id: 445c3862e019fb7b470f9c7f314fc231b62706e9
2019-04-22 18:48:45 +00:00
result->reset(
new LibradosWritableFile(_GetIoctx(fpath), fid, fpath, this, options));
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
s = Status::OK();
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief reuse write file handler
* @details
* This function will rename old_fname to new_fname,
* then return the handler of new_fname
*
* @param new_fname [description]
* @param old_fname [description]
* @param result [description]
* @param options [description]
* @return [description]
*/
Status EnvLibrados::ReuseWritableFile(
const std::string& new_fname,
const std::string& old_fname,
std::unique_ptr<WritableFile>* result,
const EnvOptions& options)
{
LOG_DEBUG("[IN]%s => %s\n", old_fname.c_str(), new_fname.c_str());
std::string src_fid, tmp_fid, src_dir, src_file, dst_dir, dst_file;
split(old_fname, &src_dir, &src_file);
split(new_fname, &dst_dir, &dst_file);
std::string src_fpath = src_dir + "/" + src_file;
std::string dst_fpath = dst_dir + "/" + dst_file;
Status r = Status::OK();
do {
r = _RenameFid(src_fpath,
dst_fpath);
if (!r.ok()) {
break;
}
Optionally wait on bytes_per_sync to smooth I/O (#5183) Summary: The existing implementation does not guarantee bytes reach disk every `bytes_per_sync` when writing SST files, or every `wal_bytes_per_sync` when writing WALs. This can cause confusing behavior for users who enable this feature to avoid large syncs during flush and compaction, but then end up hitting them anyways. My understanding of the existing behavior is we used `sync_file_range` with `SYNC_FILE_RANGE_WRITE` to submit ranges for async writeback, such that we could continue processing the next range of bytes while that I/O is happening. I believe we can preserve that benefit while also limiting how far the processing can get ahead of the I/O, which prevents huge syncs from happening when the file finishes. Consider this `sync_file_range` usage: `sync_file_range(fd_, 0, static_cast<off_t>(offset + nbytes), SYNC_FILE_RANGE_WAIT_BEFORE | SYNC_FILE_RANGE_WRITE)`. Expanding the range to start at 0 and adding the `SYNC_FILE_RANGE_WAIT_BEFORE` flag causes any pending writeback (like from a previous call to `sync_file_range`) to finish before it proceeds to submit the latest `nbytes` for writeback. The latest `nbytes` are still written back asynchronously, unless processing exceeds I/O speed, in which case the following `sync_file_range` will need to wait on it. There is a second change in this PR to use `fdatasync` when `sync_file_range` is unavailable (determined statically) or has some known problem with the underlying filesystem (determined dynamically). The above two changes only apply when the user enables a new option, `strict_bytes_per_sync`. Pull Request resolved: https://github.com/facebook/rocksdb/pull/5183 Differential Revision: D14953553 Pulled By: siying fbshipit-source-id: 445c3862e019fb7b470f9c7f314fc231b62706e9
2019-04-22 18:48:45 +00:00
result->reset(new LibradosWritableFile(_GetIoctx(dst_fpath), src_fid,
dst_fpath, this, options));
Add EnvLibrados - RocksDB Env of RADOS (#1222) EnvLibrados is a customized RocksDB Env to use RADOS as the backend file system of RocksDB. It overrides all file system related API of default Env. The easiest way to use it is just like following: std::string db_name = "test_db"; std::string config_path = "path/to/ceph/config"; DB* db; Options options; options.env = EnvLibrados(db_name, config_path); Status s = DB::Open(options, kDBPath, &db); Then EnvLibrados will forward all file read/write operation to the RADOS cluster assigned by config_path. Default pool is db_name+"_pool". There are some options that users could set for EnvLibrados. - write_buffer_size. This variable is the max buffer size for WritableFile. After reaching the buffer_max_size, EnvLibrados will sync buffer content to RADOS, then clear buffer. - db_pool. Rather than using default pool, users could set their own db pool name - wal_dir. The dir for WAL files. Because RocksDB only has 2-level structure (dir_name/file_name), the format of wal_dir is "/dir_name"(CAN'T be "/dir1/dir2"). Default wal_dir is "/wal". - wal_pool. Corresponding pool name for WAL files. Default value is db_name+"_wal_pool" The example of setting options looks like following: db_name = "test_db"; db_pool = db_name+"_pool"; wal_dir = "/wal"; wal_pool = db_name+"_wal_pool"; write_buffer_size = 1 << 20; env_ = new EnvLibrados(db_name, config, db_pool, wal_dir, wal_pool, write_buffer_size); DB* db; Options options; options.env = env_; // The last level dir name should match the dir name in prefix_pool_map options.wal_dir = "/tmp/wal"; // open DB Status s = DB::Open(options, kDBPath, &db); Librados is required to compile EnvLibrados. Then use "$make LIBRADOS=1" to compile RocksDB. If you want to only compile EnvLibrados test, just run "$ make env_librados_test LIBRADOS=1". To run env_librados_test, you need to have a running RADOS cluster with the configure file located in "../ceph/src/ceph.conf" related to "rocksdb/".
2016-07-21 18:16:34 +00:00
} while (0);
LOG_DEBUG("[OUT]%s\n", r.ToString().c_str());
return r;
}
/**
* @brief create a new directory handler
* @details [long description]
*
* @param name [description]
* @param result [description]
*
* @return [description]
*/
Status EnvLibrados::NewDirectory(
const std::string& name,
std::unique_ptr<Directory>* result)
{
LOG_DEBUG("[IN]%s\n", name.c_str());
std::string fid, dir, file;
/* just want to get dir name */
split(name + "/tmp", &dir, &file);
Status s;
do {
s = _GetFid(dir, fid);
if (!s.ok() || DIR_ID_VALUE != fid) {
s = Status::IOError(name, strerror(-ENOENT));
break;
}
if (Status::NotFound() == s) {
s = _AddFid(dir, DIR_ID_VALUE);
if (!s.ok()) break;
} else if (!s.ok()) {
break;
}
result->reset(new LibradosDirectory(_GetIoctx(dir), dir));
s = Status::OK();
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief check if fname is exist
* @details [long description]
*
* @param fname [description]
* @return [description]
*/
Status EnvLibrados::FileExists(const std::string& fname)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string fid, dir, file;
split(fname, &dir, &file);
Status s = _GetFid(dir + "/" + file, fid);
if (s.ok() && fid != DIR_ID_VALUE) {
s = Status::OK();
}
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief get subfile name of dir_in
* @details [long description]
*
* @param dir_in [description]
* @param result [description]
*
* @return [description]
*/
Status EnvLibrados::GetChildren(
const std::string& dir_in,
std::vector<std::string>* result)
{
LOG_DEBUG("[IN]%s\n", dir_in.c_str());
std::string fid, dir, file;
split(dir_in + "/temp", &dir, &file);
Status s;
do {
s = _GetFid(dir, fid);
if (!s.ok()) {
break;
}
if (fid != DIR_ID_VALUE) {
s = Status::IOError();
break;
}
s = _GetSubFnames(dir, result);
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief delete fname
* @details [long description]
*
* @param fname [description]
* @return [description]
*/
Status EnvLibrados::DeleteFile(const std::string& fname)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string fid, dir, file;
split(fname, &dir, &file);
Status s = _GetFid(dir + "/" + file, fid);
if (s.ok() && DIR_ID_VALUE != fid) {
s = _DelFid(dir + "/" + file);
} else {
s = Status::NotFound();
}
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief create new dir
* @details [long description]
*
* @param dirname [description]
* @return [description]
*/
Status EnvLibrados::CreateDir(const std::string& dirname)
{
LOG_DEBUG("[IN]%s\n", dirname.c_str());
std::string fid, dir, file;
split(dirname + "/temp", &dir, &file);
Status s = _GetFid(dir + "/" + file, fid);
do {
if (Status::NotFound() != s && fid != DIR_ID_VALUE) {
break;
} else if (Status::OK() == s && fid == DIR_ID_VALUE) {
break;
}
s = _AddFid(dir, DIR_ID_VALUE);
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief create dir if missing
* @details [long description]
*
* @param dirname [description]
* @return [description]
*/
Status EnvLibrados::CreateDirIfMissing(const std::string& dirname)
{
LOG_DEBUG("[IN]%s\n", dirname.c_str());
std::string fid, dir, file;
split(dirname + "/temp", &dir, &file);
Status s = Status::OK();
do {
s = _GetFid(dir, fid);
if (Status::NotFound() != s) {
break;
}
s = _AddFid(dir, DIR_ID_VALUE);
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief delete dir
* @details
*
* @param dirname [description]
* @return [description]
*/
Status EnvLibrados::DeleteDir(const std::string& dirname)
{
LOG_DEBUG("[IN]%s\n", dirname.c_str());
std::string fid, dir, file;
split(dirname + "/temp", &dir, &file);
Status s = Status::OK();
s = _GetFid(dir, fid);
if (s.ok() && DIR_ID_VALUE == fid) {
std::vector<std::string> subs;
s = _GetSubFnames(dir, &subs);
// if subfiles exist, can't delete dir
if (subs.size() > 0) {
s = Status::IOError();
} else {
s = _DelFid(dir);
}
} else {
s = Status::NotFound();
}
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief return file size
* @details [long description]
*
* @param fname [description]
* @param file_size [description]
*
* @return [description]
*/
Status EnvLibrados::GetFileSize(
const std::string& fname,
uint64_t* file_size)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string fid, dir, file;
split(fname, &dir, &file);
time_t mtime;
Status s;
do {
std::string fpath = dir + "/" + file;
s = _GetFid(fpath, fid);
if (!s.ok()) {
break;
}
int ret = _GetIoctx(fpath)->stat(fid, file_size, &mtime);
if (ret < 0) {
LOG_DEBUG("%i\n", ret);
if (-ENOENT == ret) {
*file_size = 0;
s = Status::OK();
} else {
s = err_to_status(ret);
}
} else {
s = Status::OK();
}
} while (0);
LOG_DEBUG("[OUT]%s|%lld\n", s.ToString().c_str(), (long long)*file_size);
return s;
}
/**
* @brief get file modification time
* @details [long description]
*
* @param fname [description]
* @param file_mtime [description]
*
* @return [description]
*/
Status EnvLibrados::GetFileModificationTime(const std::string& fname,
uint64_t* file_mtime)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string fid, dir, file;
split(fname, &dir, &file);
time_t mtime;
uint64_t file_size;
Status s = Status::OK();
do {
std::string fpath = dir + "/" + file;
s = _GetFid(dir + "/" + file, fid);
if (!s.ok()) {
break;
}
int ret = _GetIoctx(fpath)->stat(fid, &file_size, &mtime);
if (ret < 0) {
if (Status::NotFound() == err_to_status(ret)) {
*file_mtime = static_cast<uint64_t>(mtime);
s = Status::OK();
} else {
s = err_to_status(ret);
}
} else {
s = Status::OK();
}
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief rename file
* @details
*
* @param src [description]
* @param target_in [description]
*
* @return [description]
*/
Status EnvLibrados::RenameFile(
const std::string& src,
const std::string& target_in)
{
LOG_DEBUG("[IN]%s => %s\n", src.c_str(), target_in.c_str());
std::string src_fid, tmp_fid, src_dir, src_file, dst_dir, dst_file;
split(src, &src_dir, &src_file);
split(target_in, &dst_dir, &dst_file);
auto s = _RenameFid(src_dir + "/" + src_file,
dst_dir + "/" + dst_file);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief not support
* @details [long description]
*
* @param src [description]
* @param target_in [description]
*
* @return [description]
*/
Status EnvLibrados::LinkFile(
const std::string& src,
const std::string& target_in)
{
LOG_DEBUG("[IO]%s => %s\n", src.c_str(), target_in.c_str());
return Status::NotSupported();
}
/**
* @brief lock file. create if missing.
* @details [long description]
*
* It seems that LockFile is used for preventing other instance of RocksDB
* from opening up the database at the same time. From RocksDB source code,
* the invokes of LockFile are at following locations:
*
* ./db/db_impl.cc:1159: s = env_->LockFile(LockFileName(dbname_), &db_lock_); // DBImpl::Recover
* ./db/db_impl.cc:5839: Status result = env->LockFile(lockname, &lock); // Status DestroyDB
*
* When db recovery and db destroy, RocksDB will call LockFile
*
* @param fname [description]
* @param lock [description]
*
* @return [description]
*/
Status EnvLibrados::LockFile(
const std::string& fname,
FileLock** lock)
{
LOG_DEBUG("[IN]%s\n", fname.c_str());
std::string fid, dir, file;
split(fname, &dir, &file);
Status s = Status::OK();
do {
std::string fpath = dir + "/" + file;
s = _GetFid(fpath, fid);
if (Status::OK() != s &&
Status::NotFound() != s) {
break;
} else if (Status::NotFound() == s) {
s = _AddFid(fpath, _CreateFid());
if (!s.ok()) {
break;
}
} else if (Status::OK() == s && DIR_ID_VALUE == fid) {
s = Status::IOError();
break;
}
*lock = new LibradosFileLock(_GetIoctx(fpath), fpath);
} while (0);
LOG_DEBUG("[OUT]%s\n", s.ToString().c_str());
return s;
}
/**
* @brief unlock file
* @details [long description]
*
* @param lock [description]
* @return [description]
*/
Status EnvLibrados::UnlockFile(FileLock* lock)
{
LOG_DEBUG("[IO]%p\n", lock);
if (nullptr != lock) {
delete lock;
}
return Status::OK();
}
/**
* @brief not support
* @details [long description]
*
* @param db_path [description]
* @param output_path [description]
*
* @return [description]
*/
Status EnvLibrados::GetAbsolutePath(
const std::string& db_path,
std::string* output_path)
{
LOG_DEBUG("[IO]%s\n", db_path.c_str());
return Status::NotSupported();
}
/**
* @brief Get default EnvLibrados
* @details [long description]
* @return [description]
*/
EnvLibrados* EnvLibrados::Default() {
static EnvLibrados default_env(default_db_name,
std::getenv(default_config_path),
default_pool_name);
return &default_env;
}
Optionally wait on bytes_per_sync to smooth I/O (#5183) Summary: The existing implementation does not guarantee bytes reach disk every `bytes_per_sync` when writing SST files, or every `wal_bytes_per_sync` when writing WALs. This can cause confusing behavior for users who enable this feature to avoid large syncs during flush and compaction, but then end up hitting them anyways. My understanding of the existing behavior is we used `sync_file_range` with `SYNC_FILE_RANGE_WRITE` to submit ranges for async writeback, such that we could continue processing the next range of bytes while that I/O is happening. I believe we can preserve that benefit while also limiting how far the processing can get ahead of the I/O, which prevents huge syncs from happening when the file finishes. Consider this `sync_file_range` usage: `sync_file_range(fd_, 0, static_cast<off_t>(offset + nbytes), SYNC_FILE_RANGE_WAIT_BEFORE | SYNC_FILE_RANGE_WRITE)`. Expanding the range to start at 0 and adding the `SYNC_FILE_RANGE_WAIT_BEFORE` flag causes any pending writeback (like from a previous call to `sync_file_range`) to finish before it proceeds to submit the latest `nbytes` for writeback. The latest `nbytes` are still written back asynchronously, unless processing exceeds I/O speed, in which case the following `sync_file_range` will need to wait on it. There is a second change in this PR to use `fdatasync` when `sync_file_range` is unavailable (determined statically) or has some known problem with the underlying filesystem (determined dynamically). The above two changes only apply when the user enables a new option, `strict_bytes_per_sync`. Pull Request resolved: https://github.com/facebook/rocksdb/pull/5183 Differential Revision: D14953553 Pulled By: siying fbshipit-source-id: 445c3862e019fb7b470f9c7f314fc231b62706e9
2019-04-22 18:48:45 +00:00
} // namespace ROCKSDB_NAMESPACE