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Flexible Transactional Storage Russell Sears [email protected] HPTS 2005 Outline • Introduction • Problems with existing systems • A modular approach – Composable on-disk data structures – Application control of low-level primitives – Microbenchmarks • The next steps – Library optimization during application compilation – Verification of application-specific extensions • Conclusion Introduction • New applications introduce new demands for storage infrastructure – Database implementations eventually adapt • Continuous queries, database file systems, XML, OLAP – But not always • Web search, GMail, P2P • Either way, custom storage solutions fill in the cracks – Expensive; little reuse of existing infrastructure – Subtle bugs lead to data corruption Selective Reuse of Storage System Components • Expose the RSS to allow greater reuse – Berkeley DB / Sleepy Cat – Layered Databases • Proven real-world improvements in performance and code complexity • Why not provide lower level interfaces? Our Focus Query Optimizer Query Evaluator Statistics Relations Tuples Storage System Physical Access Methods Recovery / Durability Replication Page File Locking … Log File Allow applications to directly customize and reuse underlying storage primitives Design Goals • Let applications build upon or replace modules – – – – – – Allocation strategies Page layout On disk data structures Concurrency control Log (format, durability and reordering) Recovery • Improved usability and performance – Application specific data structure organization – Program specific optimizations LLADD’s Storage Interface (Lightweight Library for Atomicity and Data Durability) • Focus on simplifying the APIs within the RSS – “redo()” and “undo()” (there is no “do()”) – Subcomponents implement flexible APIs write log Tupdate() Data Structure Plugin Tset() Tread() Wrapper Function(s) op(data) Read-only Access Methods read memory invoke REDO Operation Implementation Log Manager log entries UNDO/REDO requests page updates Recovery / Abort Page File Write ahead logging implementation (Arrows point in the direction of application data flow) Reusable data structures ArrayList Linked Lists Index Page Poor locality / High overhead? Pages contain fixed length records Linear Hash Table Buckets Bucket List Internal Fragmentation? • Familiar object oriented design patterns allow data structure reuse • Nested Top Actions can be used to provide atomicity • Easy to specialize data structures Hash Table Bulk Load Time 45 Berkeley DB 40 Modular / Nested Top Actions Seconds 35 Monolithic / Well ordered writes 30 25 20 15 10 5 0 0 50000 100000 150000 200000 250000 Insertions • Layered version’s performance is competitive • Also benchmarked optimized version – No nested top actions Temporary inconsistency – Saves log bandwidth, roughly doubles throughput – Complex, monolithic code Object serialization • Persistent objects are often triple buffered System Memory File system cache DB page cache Application Data (Live objects) Disk • Turning off OS cache removes one copy • We can remove a second copy The Problem with the Page Cache • Approach #1: Reduce the number of live objects – Need to repeatedly serialize and deserialize objects – CPU intensive • Approach #2: Reduce the size of the page cache – Object updates force a write to the page cache – Two extra disk accesses (1 read, 1 write) to update an object in cache! Specialized Page Caching • Defer page update until object is evicted from application memory – Issue log writes immediately – Application cache manipulates page cache directly Object serialization performance LLADD+delta LLADD+update/flush LLADD Berkeley DB MySQL - In process / InnoDB 7000 Updates/Second 6000 5000 4000 3000 2000 1000 0 0 10 20 30 40 50 60 70 80 90 100 Percentage of Object that Changed Roughly doubled throughput while reducing memory requirements. Access Locality and Object Serialization 300 LLADD Updates/Second 250 LLADD+update/flush 200 150 100 50 0 0 20 40 60 80 Percent in Hot Set Under heavy memory pressure, the optimization allows the cache to be utilized efficiently 100 Language Based Tools • Modern programming techniques provide some interesting opportunities – Software verification – Optimization • High level interfaces make it difficult to take advantage of some of these tools • How much do we gain by moving to lower level interfaces? Memoization • Servicing a cache hit is expensive compared to a pointer traversal • Programs typically access the same page repeatedly • Simple solution: Keep a pointer to the last value returned by the page cache • Problem: Unrelated, interleaved calls – Multi-threaded code – Layered APIs Example • Consider this application code: for(int i = 0; i < len; i++) { value = hash_lookup(recordid, key[i]); } • hash_lookup() probably looks something like this: hash_lookup(…) { Page * p = pin(recordid.page); // Read hashtable header unpin(recordid.page); … // pin and unpin bucket, data pages } • Memoize header by storing values in the application’s stack frame Dynamic Checks • Insert memoization logic into application code, and store memoized values on the stack. – Preserves access locality within each thread – Handles “special cases” (B-Tree roots, iterators, etc) – Simplifies application/library source code • Implemented using CIL, a C source to source transformation library. • ~2x speedup on read-only CPU-bound hash table workload Static analysis (work in progress) • Dynamic checks are expensive • Use BLAST to remove redundant checks at compile time – Tentatively remove check and call to pin() – Ask BLAST to prove the memoized value is correct at pin()’s call site. • Assumed the original program is “well behaved” C by removing problematic constructs Verification of Invariants (future work) • Extensions to the library must follow a number of invariants – – – – Using nested top actions correctly Updating the LSN of altered pages Not relying upon transient data in redo()/undo() and so on • Want to check application code’s adherence to invariants • Hopefully, this will allow us to guarantee high level properties are met • Similar in spirit to the use of SLAM to verify Windows drivers Conclusion • Presented a simple storage architecture that supports a wide variety of applications • The architecture brings up a number of interesting research questions • A preliminary implementation is available – Ready for researchers, not for important data – http://lladd.sourceforge.net/ Acknowledgements Eric Brewer Mike Demmer Bowei Du Jimmy Kittiyachavalit Jim Blomo Jason Bayer Gilad Arnold Amir Kamil Colleen Lewis Backup Slides Database Systems Take Control Away from Developers • Great solution for established classes of applications • Leads to serious problems in unanticipated situations • A DBMS implementation can only support a finite set of semantics and must make decisions regarding – – – – Data layout / programming model Concurrency / consistency Recovery / durability Replication / scalability One Solution • Give application developers more choices – Relational / Cube / XML data models – Optimistic / pessimistic concurrency control – Serializable / Repeatable Read / Read Committed / Read Uncommitted – Disable media recovery, partial logging, no logging – 2PC, merge replication, master / slave, partitioning – and so on… • Leads to complex DBMS implementations • It takes a long time to get this right! Editing DBMS Source Code is Difficult • • • • • Requires knowledge of complex DB internals Easy to get the extensions wrong Difficult to test or debug Breaks existing functionality Leads to incompatible DB versions. Are these all just artifacts of conventional database design? Challenges • It must be easy to add new extensions, and hard to (accidentally) break existing ones. • Low level changes should not alter high level functionality in unexpected ways • Bugs in recovery logic should be obvious • In ‘interesting’ cases, should see ‘significant’ performance improvement. Multiple page formats Generic page layout: LSN Page Type Fixed length record layout: LSN Fixed Length Data Length Page type specific 1 2 Record Count … • Record id’s are of the form: (page, slot, length) • ‘slot’ is interpreted by the appropriate page format implementation; ‘length’ is for the application’s benefit. • Page Type 0 is reserved (allows lazy page initialization) Dynamic Check Example Original Code Optimized Code foo(int i, record r) { Page *p; while(i--) { r->slot++; foo(int i, record r) { Page *p = null; while(i--) { r.slot++; if(!p || p->page != r.page) { unpin(p); p = pin(r.page); } … if(...) { r.page++; r.slot = 0; } } if(p) unpin(p); } p = pin(r.page); … unpin(p); if(...) { r.page++; r.slot = 0; } } } Static Analysis Example Original Code + Dynamic Checks Optimized Code foo(int i, record r) { Page *p = pin(r.page); … while(i--) { r.slot++; if(!p || p->page != r.page) { unpin(p); p = pin(r.page); } } unpin(p); } foo(int i, record r) { Page *p = pin(r.page); … while(i--) { r.slot++; } unpin(p); } Potential applications • Tool for future database research • Improved performance from better compiler / language based optimization • New programming language primitives seek to abstract SQL away. In some cases legacy declarative interfaces may simply be getting in the way Lock Manager API • Page level locking can be supported by the buffer manager, but requires solid error handling. • Record level / index locking is tricky – Needs to understand built in and third party extensions – Plan to implement Hierarchical 2PL in a way that allows reuse by index implementations – Index implementations can simply lock the entire index if performance is not an issue. In memory vs. on disk semantics • Holy grail: Application data acts like persistent data – But we still want a bunch of database features • One solution: Map a custom declarative interface into SQL. – Don’t we still need an optimizer, etc for the in memory data? – Transactional pages look a lot like RAM, especially if you provide a library of persistent data structures that match the ones the application uses Sample Operation Implementation (1/3) // Operation Implementation // p is the bufferPool’s current copy of the page. int operateIncrement(int xid, Page *p, lsn_t lsn, recordid rid, const void * d) { inc_dec_t * arg = (inc_dec_t*)d; int i; latchRecord(p, rid); readRecord(xid, p, rid, &i); // read current value i += arg->amount; // write new value, update LSN writeRecord(xid, p, lsn, rid, &i); unlatchRecord(p, rid); return 0; // no error } Sample Operation Implementation (2/3) // register the operation ops[OP_INCREMENT].implementation= ops[OP_INCREMENT].argumentSize = // set the REDO to be the same as ops[OP_INCREMENT].redoOperation = &operateIncrement; sizeof(inc_dec_t); normal operation OP_INCREMENT; // UNDO is the inverse of REDO ops[OP_INCREMENT].undoOperation = OP_DECREMENT; // Define inc_dec_t typedef struct {int amount } inc_dec_t; Sample Operation Implementation (3/3) // User friendly wrapper function int Tincrement(int xid, recordid rid, int amount) { // rec will be serialized to the log int_dec_t rec; rec.amount = amount; // write a log entry, then execute it Tupdate(xid, rid, &rec, OP_INCREMENT); // return the incremented value int new_value // wrappers can call other wrappers Tread(xid, rid, &new_value); return new_value; } What if the database is missing a crucial feature? • An application could use the database anyway – Convoluted data and/or programming model – Performance problems • Or it could implement what it needs from scratch – Reinventing the wheel – Subtle problems with data loss and corruption Modularity of storage implementation • Focus on simplifying the APIs within the RSS – Operation implementations consist of two callbacks, “redo()” and “undo()” (there is no “do()”) – Subcomponents implement flexible APIs read memory Tread() Tset() page updates UNDO/REDO requests Read-only Access Methods Wrapper Function(s) Page File Operation Implementation op(data) App-specific extensions Recovery / Abort invoke REDO Tupdate() Log Manager write log (Arrows point in the direction of application data flow) log entries Language Based Optimization • Applications often use storage libraries in limited, predictable ways • Storage infrastructure must support all legal access patterns • Could add calls to the API to optimize special cases – Difficult to use correctly – Library contains multiple implementations of each function Longer Introduction • Conventional databases are not appropriate for some applications – It takes time to add support for new classes of applications – Niche applications may not warrant added complexity – Sometimes declarative interfaces are overkill • Low level API’s can be difficult to use – Expose intricately connected subsystems – Bugs in recovery logic – Applications must implement high-level functionality • Modern programming techniques can address these problems … • Relational databases force some decisions upon application developers: – Data model / layout – Concurrency model – Consistency model – Recovery and durability semantics – Replication system – Declarative programming models – and so on… Review of Write Ahead Logging Begin T1 P1 … Abort P2 … T1 P3 … Begin T2 P3 … Abort T1 Problem 1: Physical undo, concurrent transactions and non-atomic operations interact poorly Solution: Logical undo Problem 2: If the tree is inconsistent during recovery, logical undo fails Solution: (Nested Top Actions) Use physical undo until consistency is restored then atomically switch to logical undo