/*--- This software is copyrighted by the Regents of the University of California, and other parties. The following terms apply to all files associated with the software unless explicitly disclaimed in individual files. The authors hereby grant permission to use, copy, modify, distribute, and license this software and its documentation for any purpose, provided that existing copyright notices are retained in all copies and that this notice is included verbatim in any distributions. No written agreement, license, or royalty fee is required for any of the authorized uses. Modifications to this software may be copyrighted by their authors and need not follow the licensing terms described here, provided that the new terms are clearly indicated on the first page of each file where they apply. IN NO EVENT SHALL THE AUTHORS OR DISTRIBUTORS BE LIABLE TO ANY PARTY FOR DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OF THIS SOFTWARE, ITS DOCUMENTATION, OR ANY DERIVATIVES THEREOF, EVEN IF THE AUTHORS HAVE BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. THE AUTHORS AND DISTRIBUTORS SPECIFICALLY DISCLAIM ANY WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, AND NON-INFRINGEMENT. THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, AND THE AUTHORS AND DISTRIBUTORS HAVE NO OBLIGATION TO PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS. GOVERNMENT USE: If you are acquiring this software on behalf of the U.S. government, the Government shall have only "Restricted Rights" in the software and related documentation as defined in the Federal Acquisition Regulations (FARs) in Clause 52.227.19 (c) (2). If you are acquiring the software on behalf of the Department of Defense, the software shall be classified as "Commercial Computer Software" and the Government shall have only "Restricted Rights" as defined in Clause 252.227-7013 (c) (1) of DFARs. Notwithstanding the foregoing, the authors grant the U.S. Government and others acting in its behalf permission to use and distribute the software in accordance with the terms specified in this license. ---*/ /** * @defgroup LLADD_CORE Core API * * The minimal subset of Stasis necessary to implement transactional consistency. * * This module includes the standard API (excluding operations), the * logger, the buffer mananger, and recovery code. * * In theory, the other .h files that are installed in /usr/include * aren't needed for application developers. * * @todo Move as much of the stuff in lladd/ to src/lladd/ as possible. Alternatively, move all headers to lladd/, and be done with it! * */ /** @mainpage Introduction to Stasis @section compiling Compiling and installation Prerequisites: - automake 1.8+: needed to build from CVS - check: A unit testing framework (needed to run the self-tests) Optional: - libconfuse: Used by older networking code to parse configuration options. - BerkeleyDB: Used by the benchmarking code for purposes of comparison. Development is currently performed under Debian's Testing branch. To compile Stasis, first check out a copy with SVN. If you have commit access: @code svn co --username username https://stasis.googlecode.com/svn/trunk stasis @endcode For anonymous checkout: svn co http://stasis.googlecode.com/svn/trunk stasis then: @code $ ./reconf $ ./configure --quiet $ make -j4 > /dev/null $ cd test/stasis $ make check @endcode This will fail if your system defaults to an old (pre-1.7) version of autotools. Fortunately, multiple versions of autotools may exist on the same system. Execute the following commands to compile with version 1.8 of autotools: @code $ ./reconf-1.8 $ ./configure --quiet $ make -j4 > /dev/null $ cd test/stasis $ make check @endcode Of course, you can omit "--quiet" and "> /dev/null", but configure and make both produce quite a bit of output that may obscure useful warning messages. 'make install' is currently unsupported. Look in utilities/ for an example of a simple program that uses Stasis. Currently, most generally useful programs written on top of Stasis belong in stasis/src/apps, while utilities/ contains programs useful for debugging the library. @section usage Using Stasis in your software Synopsis: @include examples/ex1.c Hopefully, Tbegin(), Talloc(), Tset(), Tcommit(), Tabort() and Tdealloc() are self explanatory. If not, they are covered in detail elsewhere. Tinit() and Tdeinit() initialize the library, and clean up when the program is finished. Other partiularly useful functions are ThashCreate(), ThashDelete(), ThashInsert(), ThashRemove(), and ThashLookup() which provide a re-entrant linear hash implementation. ThashIterator() and ThashNext() provide an iterator over the hashtable's values. @subsection bootstrap Reopening a closed data store Stasis imposes as little structure upon the application's data structures as possible. Therefore, it does not maintain any information about the contents or naming of objects within the page file. This means that the application must maintain such information manually. In order to facilitate this, Stasis provides the function TgetRecordType() and guarantees that the first recordid returned by any allocation will point to the same page and slot as the constant ROOT_RECORD. TgetRecordType will return NULLRID if the record passed to it does not exist. Therefore, the following code will safely initialize or reopen a data store: @include examples/ex2.c @see test.c for a complete, executable example of reopeneing an existing store. @todo Explain how to determine the correct value of rootEntry.size in the case of a hashtable. @see OPERATIONS for more operations that may be useful for your software. @subsection consistency Using Stasis in multithreaded applications. Unless otherwise noted, Stasis' operations are re-entrant. This means that an application may call them concurrently without corrupting Stasis' internal data structures. However, if two threads attempt to write the same data value simultaneously, the result is undefined. In database terms, Stasis uses latches to protect its own data structures' consistency (including those on disk), but does not obtain short term read or write locks to protect data as it is being written. This is less consistency than SQL's Level 0 (Dirty Reads) provides. Some of Stasis' data structures do obtain short read and write locks automatically. Refer to individual data structues for more information. Stasis' allocation functions, such as Talloc(), do not reuse space that was freed by an ongoing transaction. This means that you may safely overwrite freshly allocated space without writing undo entries, and allows concurrent transactions to safely allocate space. From the point of view of conventional multithreaded software development, Stasis closely matches the semantics provided by typical operating system thread implementations. However, it allows transactions to abort and rollback independently of each other. This means that transactions may observe the effects of transactions that will eventually abort. Finally, Stasis asumes that each thread has its own transaction; concurrent calls within the same transaction are not supported. This restriction may be removed in the future. @section selfTest The test suite Stasis includes an extensive unit test suite which may be invoked by running 'make check' in Stasis' root directory. Some of the tests are for older, unmaintained code that was built on top of Stasis. Running 'make check' in test/stasis runs all of the Stasis tests without running the obsolete tests. @section archictecture Stasis' structure This section is geared toward people that would like to extend Stasis. The OSDI paper provides a higher level description and motivation for the architecture. This section describes naming conventions used to distinguish between different portions of Stasis, and provides an overview of memory management and mutex acquisition conventions. This section does not describe recovery, transaction initiation, etc. Those methods change less frequently. Instead of focusing on them, this text focuses on the issues faced by transactional data structures. Stasis components can be classified as follows: - I/O utilities (file handles, OS compatibility wrappers) - Write ahead logging component interfaces (logger.h, XXX) - Write ahead logging component implementations (hash based buffer manager, in memory log, etc...) - Page formats and associated operations (page/slotted.c page/fixed.c) - Application visible methods (Talloc, Tset, ThashInsert, etc) @subsection layoutNaming Directory layout The Stasis repository contains the following "interesting" directories: @par $STASIS/stasis/ Contains the header directory structure. In theory, this contains all of the .h files that need to be installed for a fully functional Stasis development environment. In practice, .h files in src/ are also needed in some cases. The separation of .h files between src/ and stasis/ continues for various obscure reasons, including CVS's lack of a "move" command. For now, .h files should be placed with similar .h files, or in stasis/ if no such files exist. The directory structure of stasis/ mirrors that of src/ @par $STASIS/src/ Contains the .c files @par $STASIS/src/stasis Contains Stasis and the implementations of its standard modules. The subdirectories group files by the type of module they implement. @note By convention, when the rest of this document says foo/, it is referring to two directories: stasis/foo/ and src/stasis/foo/. Unless it's clear from context, a file without an explicit directory name is in stasis/ or src/stasis/. In order to refer to files and directories outside of these two locations, but still in the repository, this document will use the notation $STASIS/dir. @note This is done for brevity, and to avoid coupling documentation to the (deprecated) placement of .h files under src/. @note Example: The transactional data structure implementations in operations/ can be found in $STASIS/src/stasis/operations/ and $STASIS/stasis/operations/. @subsection Modules Stasis is implemented in C, but is structured in a somewhat object oriented style. There are a number of different "modules", for lack of a better term. Each implementation in the module lives in the module's subdirectory. Code that is common to many implementation, and headers that define per-module functions live in files named after the module. Example: The io module contains the following files: @code io.h io.c io/handle.h io/debug.c io/file.c io/memory.c io/non_blocking.c io/rangeTracker.h io/rangeTracker.c @endcode In this case, rangeTracker.c and io.c are the only files containing more than one non-static method, so they are the only ones that have corresponding .h files. rangeTracker.c is implementing a data structure that is being used by the other files. debug.c, file.c, memory.c and non_blocking.c each implements a different type of handle. Some modules are simply groups of files that perform similar tasks, or make use of the same set of interfaces (eg: page/ and operations/). Files in these directories may make use of the same utility functions, but aren't implementing the same interface. Other modules provide multiple implementations of the same interface (eg: io/ and logger/). C doesn't have inheritance, so Stasis "fakes it" using one of two methods. In both cases, a struct is defined to contain a void pointer, which the implementation manually casts to the appropriate type: @par Dispatch functions The dispatch functions contain a switch statement or conditional that decides which implementation to call. Calling convention: @code bird_carry(african_swallow, coconut); @endcode @par struct of function pointers These functions use the following calling convention: @code african_swallow->carry(african_swallow,coconut) @endcode @subsection ioutil I/O utilities The I/O utilities live in io/. They provide reentrant, interfaces. This was written to insulate Stasis from Linux's ever-evolving I/O system calls, for portability, and to allow (for example) in-memory operation. @subsection walin WAL Modules None of these modules understand page formats; at this level everything is either - a page with an LSN (a version number),or - a log entry with an associated operation (redo / undo functions). Interesting files from modules in this part of Stasis include logger2.c, bufferManager.c, and recovery2.c. @subsection page Page Formats XXX: I ran out of time here. The rest of the documentation is incomplete, but might point in the right direction. Discuss readRecord, writeRecord (high level page access methods) and their implemetnations in slotted.c, fixed.c, etc. XXX: Then explain the latching convention. (Also, explain which latches are not to be used by page implementations, and which latches may not be used by higher level code.) @subsection appfunc Application visible methods These methods start with "T". Look at the examples above. These are the "wrapper functions" from the OSDI paper. They are supported by operation implementations, which can be found in the operations/ directory. @section extending Implementing you own operations @todo Provide a tutorial that explains how to extend Stasis with new operations. @see increment.h for an example of a very simple logical operation. @see linearHashNTA.h for a more sophisticated example that makes use of Nested Top Actions. */ /** * @defgroup OPERATIONS Logical Operations * * Implementations of logical operations, and the interfaces that allow new operations to be added. * * @todo Write a brief howto to explain the implementation of new operations. * */ /** * @file * * Defines Stasis' primary interface. * * * * @todo error handling * * @ingroup LLADD_CORE * $Id$ */ #ifndef __TRANSACTIONAL_H__ #define __TRANSACTIONAL_H__ #include "common.h" BEGIN_C_DECLS /** * represents how to look up a record on a page * @todo recordid.page should be 64bit. * @todo int64_t (for recordid.size) is a stopgap fix. */ typedef struct { int page; // XXX needs to be pageid_t, but that breaks unit tests. int slot; int64_t size; //signed long long size; } recordid; typedef struct { size_t offset; size_t size; // unsigned fd : 1; } blob_record_t; extern const recordid ROOT_RECORD; extern const recordid NULLRID; /** If a recordid's slot field is set to this, then the recordid represents an array of fixed-length records starting at slot zero of the recordid's page. @todo Support read-only arrays of variable length records, and then someday read / write / insert / delete arrays... */ #define RECORD_ARRAY (-1) #include "operations.h" /** * Currently, Stasis has a fixed number of transactions that may be * active at one time. */ #define EXCEED_MAX_TRANSACTIONS 1 /** * @param xid transaction ID * @param LSN last log that this transaction used */ typedef struct { int xid; long LSN; } Transaction; /** * initialize the transactional system, including running recover (if * necessary), building the operations_table, and opening the logs * @return 0 on success * @throws error code on error */ int Tinit(); /** * @return positive transaction ID on success, negative return value on error */ int Tbegin(); /** * Used when extending Stasis. * Operation implementors should wrap around this function to provide more mnuemonic names. * * @param xid The current transaction. * @param rid The record the operation pertains to. For some logical operations, this will be a dummy record. * @param dat Application specific data to be recorded in the log (for undo/redo), and to be passed to the implementation of op. * @param op The operation's offset in operationsTable * * @see operations.h set.h */ compensated_function void Tupdate(int xid, recordid rid, const void *dat, int op); compensated_function void TupdateStr(int xid, recordid rid, const char *dat, int op); compensated_function void TupdateRaw(int xid, recordid rid, const void *dat, int op); compensated_function void TupdateDeferred(int xid, recordid rid, const void *dat, int op); /** * @param xid transaction ID * @param rid reference to page/slot * @param dat buffer into which data goes */ compensated_function void Tread(int xid, recordid rid, void *dat); compensated_function void TreadStr(int xid, recordid rid, char *dat); /** * Commit an active transaction. Each transaction should be completed * with exactly one call to Tcommit() or Tabort(). * * @param xid transaction ID * @return 0 on success */ int Tcommit(int xid); /** * Abort (rollback) an active transaction. Each transaction should be * completed with exactly one call to Tcommit() or Tabort(). * * @param xid transaction ID * @return 0 on success, -1 on error. */ int Tabort(int xid); /** * flushes all pages, cleans up log * @return 0 on success * @throws error value on error */ int Tdeinit(); /** * Used by the recovery process. * Revives Tprepare'ed transactions. * * @param xid The xid that is to be revived. * @param lsn The lsn of that xid's most recent PREPARE entry in the log. */ void Trevive(int xid, long lsn); /** * Used by the recovery process. * * Sets the number of active transactions. * Should not be used elsewhere. * * @param xid The new active transaction count. */ void TsetXIDCount(int xid); /** * Checks to see if a transaction is still active. * * @param xid The transaction id to be tested. * @return true if the transacation is still running, false otherwise. */ int TisActiveTransaction(int xid); /** This is used by log truncation. */ lsn_t transactions_minRecLSN(); /** Report Stasis' current durablity guarantees. @return VOLATILE if the data will be lost after Tdeinit(), or a crash, PERSISTENT if the data will be written back to disk after Tdeinit(), but may be corrupted at crash, or DURABLE if Stasis will apply committed transactions, and roll back active transactions after a crash. */ int TdurabilityLevel(); END_C_DECLS #endif