1095 lines
52 KiB
TeX
1095 lines
52 KiB
TeX
% TEMPLATE for Usenix papers, specifically to meet requirements of
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% USENIX '05
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% originally a template for producing IEEE-format articles using LaTeX.
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% written by Matthew Ward, CS Department, Worcester Polytechnic Institute.
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% adapted by David Beazley for his excellent SWIG paper in Proceedings,
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% Tcl 96
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% turned into a smartass generic template by De Clarke, with thanks to
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% both the above pioneers
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% use at your own risk. Complaints to /dev/null.
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% make it two column with no page numbering, default is 10 point
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% Munged by Fred Douglis <douglis@research.att.com> 10/97 to separate
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% the .sty file from the LaTeX source template, so that people can
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% more easily include the .sty file into an existing document. Also
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% changed to more closely follow the style guidelines as represented
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% by the Word sample file.
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% This version uses the latex2e styles, not the very ancient 2.09 stuff.
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\documentclass[letterpaper,twocolumn,10pt]{article}
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\usepackage{usenix,epsfig,endnotes,xspace,color}
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% Name candidates:
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% Anza
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% Void
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% Station (from Genesis's "Grand Central" component)
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% TARDIS: Atomic, Recoverable, Datamodel Independent Storage
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% EAB: flex, basis, stable, dura
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\newcommand{\yad}{Void\xspace}
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\newcommand{\oasys}{Juicer\xspace}
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\newcommand{\eab}[1]{\textcolor{red}{\bf EAB: #1}}
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\newcommand{\rcs}[1]{\textcolor{green}{\bf RCS: #1}}
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\newcommand{\mjd}[1]{\textcolor{blue}{\bf MJD: #1}}
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\newcommand{\eat}[1]{}
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\begin{document}
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%don't want date printed
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\date{}
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%make title bold and 14 pt font (Latex default is non-bold, 16 pt)
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\title{\Large \bf \yad: A Terrific Application and Fascinating Paper}
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%for single author (just remove % characters)
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\author{
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{\rm Russell Sears}\\
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UC Berkeley
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\and
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{\rm Eric Brewer}\\
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UC Berkeley
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} % end author
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\maketitle
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% Use the following at camera-ready time to suppress page numbers.
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% Comment it out when you first submit the paper for review.
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%\thispagestyle{empty}
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\subsection*{Abstract}
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The is an increasing need to manage data well in a wide variety of
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systems, including robust support for atomic durable concurrent
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transactions. Databases provide the default solution, but force
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applications to interact via SQL and to forfeit control over data
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layout and access mechanisms. We argue there is a gap between DBMSs and file systems that limits designers of data-oriented applications.
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\yad is a storage framework that incorporates ideas from traditional
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write-ahead-logging storage algorithms and file systems,
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while providing applications with flexible control over data structure, layout and performance vs. robustness tradeoffs.
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% increased control over their
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%underlying modules. Generic transactional storage systems such as SQL
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%and BerkeleyDB serve many applications well, but impose constraints
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%that are undesirable to developers of system software and
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%high-performance applications. Conversely, while filesystems place
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%few constraints on applications, the do not provide atomicity or
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%durability properties that naturally correspond to application needs.
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\yad enables the development of
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unforeseen variants on transactional storage by generalizing
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write-ahead-logging algorithms. Our partial implementation of these
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ideas already provides specialized (and cleaner) semantics and
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improved performance to applications.
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%Applications may use our modular library of basic data strctures to
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%compose new concurrent transactional access methods, or write their
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%own from scratch.
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We present examples that make use of custom access methods,
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modifed buffer manager semantics, direct log file manipulation, and
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LSN-free pages that facilitate zero-copy optimizations, and discusses
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the composability of these extensions.
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||
|
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%We argue that our ability to support such a diverse range of
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%transactional systems stems directly from our rejection of
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%assumptions made by early database designers. These assumptions
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%permeate ``database toolkit'' research. We attribute the success of
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%low-level transaction processing libraries (such as Berkeley DB) to
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%a partial break from traditional database dogma.
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% entries, and
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% to reduce memory and
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%CPU overhead, reorder log entries for increased efficiency, and do
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%away with per-page LSNs in order to perform zero-copy transactional
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%I/O.
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%We argue that encapsulation allows applications to compose
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%extensions.
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%These ideas have been partially implemented, and initial performance
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%figures, and experience using the library compare favorably with
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%existing systems.
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\section{Introduction}
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%It is well known that, to a system implementor, high-level
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%abstractions built into low-level services are at best a nuisance, and
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%often lead to the circumvention or complete reimplementation of
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%complex, hardware-dependent code.
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||
|
||
%This work is based on the premise that as reliability and performance
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||
%issues have forced ``low-level'' operating system software to
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%incorporate database services such as durability and isolation. As
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%this has happened, the abstractions provided by database systems have
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%seriously restricted system designs and implementations.
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\eab{cut?:
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Approximately a decade ago, the operating systems research community came to
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the painful realization that the presence of high level abstractions
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in ``unavoidable'' system components precluded the development of
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crucial, performance sensitive applications.~\cite{exterminate, stonebrakerDatabaseDig}}
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||
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As our reliance on computing infrastructure has increased, the need
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for robust data management has increased greatly, as has the range of
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applications and systems that need it. Traditionally, data management
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has been the province of database management systems, which although
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well-suited to enterprise applications, leads to poor support for a
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wide-range systems including grid and scientific computing,
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bioinformatics, search engines, version control, and workflow
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applications. These applications need transactions but don't fit well
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onto SQL and the monolithic approach of current databases. And in
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fact, DBMSs are often not used for these systems, which must then
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implement their own ad-hoc data management tools on top of file
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systems.
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%Examples include:
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%\begin{itemize}
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%\item Search engines
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%\item Document repositories (including desktop search)
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%\item Web based email services
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%\item Web based map and gis services
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%\item Ticket reservation systems
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%\item Photo, audio and video repositories
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%\item Bioinformatics
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%\item Version control systems
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%\item Workflow applications
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%\item CAD/VLSI applications
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%\item Directory services
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%\end{itemize}
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A typical example of this mismatch is in the support for
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persistent objects in Java, called {\em Enterprise Java Beans}
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(EJB). In a typical usage, an array of objects is made persistent by
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mapping each object to a row in a table (or sometimes multiple
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tables~\cite[xxx]) and then issuing queries to keep the objects and
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rows consistent. A typical update must confirm it has the current
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version, modify the object, write out a serialized version using the
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SQL update command and commit. This is an awkward and slow mechanism;
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we show up to a 5x speedup over a MySQL implementation that is
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optimized for single-threaded, local access (Section XXX).
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\eat{
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Examples of real world systems that currently fall into this category
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are web search engines, document repositories, large-scale web-email
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services, map and trip planning services, ticket reservation systems,
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photo and video repositories, bioinformatics, version control systems,
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workflow applications, CAD/VLSI applications and directory services.
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In short, we believe that a fundamental architectural shift in
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transactional storage is necessary before general purpose storage
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systems are of practical use to modern applications.
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Until this change occurs, databases' imposition of unwanted
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abstraction upon their users will restrict system designs and
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implementations.
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}
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%In short, reliable data managment has become as unavoidable as any
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%other operating system service. As this has happened, database
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%designs have not incorporated this decade-old lesson from operating
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%systems research:
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%
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%\begin{quote} The defining tragedy of the operating systems community
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% has been the definition of an operating system as software that both
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% multiplexes and {\em abstracts} physical resources...The solution we
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% propose is simple: complete elimination of operating sytems
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% abstractions by lowering the operating system interface to the
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% hardware level~\cite{engler95}.
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%\end{quote}
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The widespread success of lower-level transactional storage libraries
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(such as Berkeley DB) is a sign of these trends. However, the level
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of abstraction provided by these systems is well above the hardware
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level, and applications that resort to ad-hoc storage mechanisms are
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still common.
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This paper presents \yad, a library that provides transactional
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storage at a level of abstraction as close to the hardware as
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possible. The library can support special purpose, transactional
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storage interfaces as well as ACID database-style interfaces to
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abstract data models.
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Notably, \yad incorporates many existing technologies from the storage
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communities, and allows applications to incorporate appropriate
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subsystems as necessary. A partial open-source implementation of the
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ideas presented below is available; performance numbers are provided
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when possible.
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Taken from sosp:
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By {\em flexible} we mean that \yad{} can implement a wide
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range of transactional data structures, that it can support a variety
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of policies for locking, commit, clusters and buffer management.
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Also, it is extensible for both new core operations
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and new data structures. It is this flexibility that allows the
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support of a wide range of systems.
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By {\em complete} we mean full redo/undo logging that supports
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both {\em no force}, which provides durability with only log writes,
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and {\em steal}, which allows dirty pages to be written out prematurely
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to reduce memory pressure. By complete, we also
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mean support for media recovery, which is the ability to roll
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forward from an archived copy, and support for error-handling,
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clusters, and multithreading. These requirements are difficult
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to meet and form the {\em raison d'\^etre} for \yad{}: the framework
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delivers these properties as reusable building blocks for systems
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to implement complete transactions.
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---
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\eab{need to talk about positive examples: LRVM, Berk DB, windows registry? Grid FS from Wisconsin}
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Applications that have only recently begun to make use of high-level
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database features include XML based systems, object persistance
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mechanisms, and enterprise management systems (notably, SAP R/3).
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**We've explained why the sky is falling. Now, explain why \yad is
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so good. (Take ideas from old paper.)**
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\section{\yad is not a Database}
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Database research has a long history, including the development of
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many technologies that our system builds upon. This section explains
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why databases are fundamentally inappropriate tools for system
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developers. The problems we present here have been the focus of
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database systems and research projects for at least 25 years.
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The section concludes with a discussion of database systems that
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attempt to address these problems. Although these systems were
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successful in many respects, they failed to address the broad class of
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software we are interested in.
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\subsection{The database abstraction}
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Database systems are often thought of in terms of the high-level
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abstractions they present. For instance, Relational database systems
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implement the relation model~\cite{cobb}, while object oriented
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databases implement object abstractions, XML databases implement
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hierarchical datasets, and so on. Before the relational model,
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navigational databases implemented a navigational, pointer and record
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based data model.
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An early survey of database implementations sought to enumerate the
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fundamental components used by database system implementors. This
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survey was performed due to difficulties in extending database systems
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into new application domains. The survey divided databases into two
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broad modules: conceptual mappings~\cite{batoryConceptual} and the
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physical database~\cite{batoryPhysical} model.
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A conceptual mapping may translate a relation into a set of keyed
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tuples. A physical model may translate a set of tuples into an
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on-disk B-Tree with support for iterators and range-based query
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operations.
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It is the responsibility of a database implementor to choose a set of
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conceptual mappings that implement the desired higher level
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abstraction (such as the relational model). The physical data model
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is chosen to efficiently support the set of mappings that are built on
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top of it.
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{\em The key observation of this paper is that no known physical data model
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can support more than a small percentage of today's applications.}
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Instead of attempting to create such a model after decades of database
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research has failed to produce one, we opt to provide a storage model
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that mimics the primitives provided by modern hardware as closely as
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possible. This makes it easy for system designers to implement most
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of the data models that the underlying hardware can support.
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\subsection{Recent survey}
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A recent survey~\cite{riscDB} enumerates problems that plague users of
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state-of-the-art database systems.
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The survey finds that database implementations fail to support the
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needs of modern systems. In large systems, this manifests itself as
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||
managability and tuning issues that prevent databases from effectively
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servicing large scale, diverse, interactive workloads. On smaller
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systems, footprint, predictable performance, and power consumption are
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primary concerns that remain troublesome.
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%Database applications that must scale up to large numbers of
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%independent, self-administering desktop installations will be
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%problematic unless a number of open research problems are solved.
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The survey also provides evidence that declarative languages such as SQL are problematic.
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Although SQL serves some classes of applications well, it is
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often inadequate for algorithmic and hierarchical computing tasks.
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Finally, complete, modern database
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implementations are often incomprehensible and
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irreproducable, hindering further research. After making these
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points, the study concludes by suggesting the adoption of ``RISC''
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style database architectures, both as a research and as an
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implementation tool~\cite{riscDB}.
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%For example, large scale application such as web search, map services,
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%e-mail use databases to store unstructured binary data, if at all.
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%More recently, WinFS, Microsoft's database based
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%file metadata management system, has been replaced in favor of an
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%embedded indexing engine that imposes less structure (and provides
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%fewer consistency guarantees) than the original
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||
%proposal~\cite{needtocitesomething}.
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||
|
||
%Scaling to the very large doesn't work (SAP used DB2 as a hash table
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||
%for years), search engines, cad/vlsi didn't happen. scalable GIS
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%systems use shredded blobs (terraserver, google maps), scaling to many
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%was more difficult than implementing from scratch (winfs), scaling
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%down doesn't work (variance in performance, footprint),
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%\subsection{Database Toolkits}
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%\yad is a library that could be used to provide the storage primatives needed by a
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%database server. Therefore, one might suppose that \yad is a database
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%toolkit. However, such an assumption would be incorrect, as \yad incorporates neither of the two basic concepts that underly database toolkit designs. These two concepts are
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%{\em conceptual-to-internal mappings}~\cite{batoryConceptual}
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%and {\em physical database models}~\cite{batoryPhysical}.
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%
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%Conceptual-to-internal mappings and physical database models were
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%discovered during an early survey of database implementations. Mappings
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%describe the computational primitives upon which client applications must
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%be implemented. Physical database models define the on-disk layout used
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%by a system in terms of data layouts and representations that are commonly
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%used by relational and navigational database implementations.
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%
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||
%Both concepts are fundamentally incompatible with a general storage
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%implementation. By definition, database servers (and toolkits) encode both
|
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%concepts, while transaction processing libraries manage to avoid complex
|
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%conceptual mappings. \yad's novelty stems from the fact that it avoids
|
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%both concepts, while making it easy for applications to incorporate results from the database
|
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%literature.
|
||
|
||
|
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%\subsubsection{Conceptual mappings}
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%
|
||
%At the time of their introduction, ten
|
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%conceptual-to-internal mappings were sufficient to describe existing
|
||
%database systems. These mappings included indexing, encoding
|
||
%(compression, encryption, etc), segmentation (along field boundaries),
|
||
%fragmentation (without regard to fields), $n:m$ pointers, and
|
||
%horizontal partitioning, among others.
|
||
%
|
||
%The initial survey postulates that a finite number of such mappings
|
||
%are adequate to describe database systems. A
|
||
%database toolkit need only implement each type of mapping in order to
|
||
%encode the set of all conceivable database systems.
|
||
%
|
||
%Our work's primary concern is to support systems beyond database
|
||
%implementations. Therefore, our system must support a more general
|
||
%set of primitives than existing systems. Defining a universal (but
|
||
%practical) framework that encompasses such a broad class of
|
||
%computation is clearly unrealistic.
|
||
%
|
||
%Therefore, \yad's architecture avoids hard-coded assumptions regarding
|
||
%the computation or abstract data types of the applications built on
|
||
%top of it.
|
||
%
|
||
\rcs{ This belongs somewhere else: Instead, it leaves decisions regarding abstract data types and
|
||
algorithm design to system developers or language designers. For
|
||
instance, while \yad has no concept of object oriented data types, two
|
||
radically different approaches toward object persistance have been
|
||
implemented on top of it~\ref{oasys}.}
|
||
|
||
\rcs{We could have just as easily written a persistance mechanism for a
|
||
functional programming language, or a particular application (such as
|
||
an email server). Our experience building data manipulation routines
|
||
on top of application-specific primitives was favorable compared to
|
||
past experiences attempting to restructure entire applications to
|
||
match pre-existing computational models, such as SQL's declarative
|
||
interface.}
|
||
|
||
%\subsubsection{Physical data models}
|
||
%
|
||
%As it was initially tempting to say that \yad was a database toolkit,
|
||
%it may now be tempting to claim that \yad implements a physical
|
||
%database model. In this section, we discuss fundamental limitations
|
||
%of the physical data model, and explain how \yad avoids these
|
||
%limitations.
|
||
|
||
We discuss Berkeley DB, and show that it provides funcationality
|
||
similar to a physical database model. Just as \yad allows
|
||
applications to build mappings on top of the primitives it provides,
|
||
\yad's design allows them to take design storage in terms of a
|
||
physical database model. Therefore, while Berkeley DB could be implemented on top
|
||
of \yad, Berkeley DB cannot support the primitives provided by \yad.
|
||
|
||
Genesis~\cite{genesis}, an early database toolkit, was built in terms
|
||
of interchangable primitives that implemented the interfaces of an
|
||
early database implementation model. It built upon the idea of
|
||
conceptual mappings described above, and the physical database model
|
||
decribed here.
|
||
|
||
%The physical database model provides the abstraction upon which
|
||
%conceptual mappings can be built. It is based on a partitioning of storage into
|
||
%{\em simple files}, which provide operations associated with key based storage, and
|
||
%{\em linksets}, which make use of various pointer storage schemes to provide
|
||
%mappings between records in simple files~\cite{batoryPhysical}.
|
||
|
||
Subsequent database toolkit work builds upon these foundations,
|
||
Exodus~\cite{exodus} and Starburst~\cite{starburst} are notable
|
||
examples, and incorporated a number of ideas that will be referred to
|
||
later in this paper. Although further discussion is beyond the scope
|
||
of this paper, object-oriented database systems, and relational
|
||
databases with support for user-definable abstract data types (such as
|
||
in Postgres~\cite{postgres}) were the primary competitors to these
|
||
database toolkits, and are the precursors to the user definable types
|
||
present in current database systems.
|
||
|
||
One can characterise the difference between database toolkits and
|
||
extensible database servers in terms of early and late binding. With
|
||
a database toolkit, new types are defined when the database server is
|
||
compiled. In today's object-relational database systems, new types
|
||
are defined at runtime. Each approach has its advantages. However,
|
||
both types of systems attempted to provide similar levels of
|
||
abstraction and flexibility to their end users.
|
||
|
||
Therefore, the database toolkit approach is inappropriate for
|
||
applications not well serviced by modern database systems.
|
||
|
||
\eat{Therefore, \yad abandons the concept of a physical database. Instead
|
||
of forcing applications to reason in terms of simple files and
|
||
linksets, it allows applications to reason about storage in terms of
|
||
atomically applicable changes to the page file. Of course,
|
||
applications that wish to reason in terms of linksets and simple files
|
||
are free to do so.
|
||
|
||
We regret forcing applications to arrange for updates to be atomic, but
|
||
this restriction is fundamental if we wish to support concurrent
|
||
transactions, durability and recovery using conventional hardware
|
||
systems. In Section~\ref{nestedTopActions} we explain how a set of
|
||
atomic changes may be atomically applied to the page file, alleviating
|
||
the burden we place upon applications somewhat.}
|
||
|
||
Now that we have introduced the underlying concepts of database
|
||
toolkits, we can discuss the proposed RISC database architectures
|
||
in more detail. RISC databases have many elements in common with
|
||
database toolkits. However, they take the database toolkit idea one
|
||
step further, and suggest standardizing the interfaces of the
|
||
toolkit's internal components, allowing multiple organizations to
|
||
compete to improve each module. The idea is to produce a research
|
||
platform, and to address issues that affect modern
|
||
databases, such as automatic performance tuning, and reducing the
|
||
effort required to implement a new database system~\cite{riscDB}.
|
||
|
||
Although we agree with the motivations behind RISC databases, instead of
|
||
building a modular database, we seek to build a system that allows
|
||
programmers to avoid databases.
|
||
|
||
|
||
\subsection{Transaction processing libraries}
|
||
|
||
Berkeley DB is a highly successful alternative to conventional
|
||
database design. At its core, it provides the physical database, or
|
||
the relational storage system of a conventional database server.
|
||
|
||
This module focuses on providing fully transactional data storage with
|
||
B-Tree and hashtable based indexes. Berkeley DB also provides some
|
||
support for application specific access methods, as did Genesis, and
|
||
the database toolkits that succeeded it~\cite{libtp}. Finally,
|
||
Berkeley DB allows applications that need to modify the recovery
|
||
semantics of Berkeley DB, or otherwise tweak the way its
|
||
write-ahead-logging protocol works to pass flags via its API.
|
||
|
||
Transaction processing libraries such as Berkeley DB are \yad's closest relative.
|
||
However, they encode a physical data model, and hardcode many
|
||
assumptions regarding workloads and decisions regarding low level data
|
||
representation. While Berkeley DB could be built on top of \yad,
|
||
Berkeley DB is too specialized to support \yad.
|
||
|
||
The Boxwood system provides a networked, fault-tolerant transactional
|
||
B-Tree and ``Chunk Manager.'' We believe that \yad is an interesting
|
||
complement to such a system, especially given \yad's focus on
|
||
intelligence and optimizations within a single node, and Boxwoods
|
||
focus on multiple node systems. In particular, when implementing
|
||
applications with predictable locality properties, it would be
|
||
interesting to explore extensions to the Boxwood approach that make
|
||
use of \yad's customizable semantics (Section~\ref{wal}), and fully logical logging
|
||
mechanism. (Section~\ref{logging})
|
||
|
||
|
||
% This part of the rant belongs in some other paper:
|
||
%
|
||
%Offer rebuttal to the Asilomar Report. On the web 2.0, no one knows
|
||
%you implemeneted your web service with perl and duct tape... Is it
|
||
%possible to scale to 1,000,000's of datastores without punting on the
|
||
%data model? (HTML suggests not...) Argue that C bindings are be the
|
||
%<25>universal glue<75> the RISC db paper should be asking for.
|
||
|
||
%cover P2 (the old one, not "Pier 2" if there is time...
|
||
|
||
\section{Write ahead loging}
|
||
|
||
This section describes how \yad uses write-ahead-logging to support the
|
||
four properties of transactional storage: Atomicity, Consistency,
|
||
Isolation and Durability. Like existing transactional storage sytems,
|
||
\yad allows applications to opt out or modify the semantics of each of
|
||
these properties.
|
||
|
||
However, \yad takes customization of transactional semantics one step
|
||
further, allowing applications to add support for transactional
|
||
semantics that we have not anticipated. While we do not believe that
|
||
we can anticipate every possible variation of write ahead logging, we
|
||
have observed that most changes that we are interested in making
|
||
involve quite a few common underlying primitives. As we have
|
||
implemented new extensions, we have located portions of the system
|
||
that are prone to change, and have extended the API accordingly. Our
|
||
goal is to allow applications to implement their own modules to
|
||
replace our implementations of each of the major write ahead logging
|
||
components.
|
||
|
||
\subsection{Operation semantics}
|
||
|
||
The smallest unit of a \yad transaction is the {\em operation}. An
|
||
operation consists of a {\em redo} function, {\em undo} function, and
|
||
a log format. At runtime or if recovery decides to reapply the
|
||
operation, the redo function is invoked with the contents of the log
|
||
entry as an argument. During abort, or if recovery decides to undo
|
||
the operation, the undo function is invoked with the contents of the
|
||
log as an argument. Like Berkeley DB, and most database toolkits, we
|
||
allow system designers to define new operations. Unlike earlier
|
||
systems, we have based our library of operations on object oriented
|
||
collection libraries, and have built complex index structures from
|
||
simpler structures. These modules are all directly avaialable,
|
||
providing a wide range of data structures to applications, and
|
||
facilitating the develop of more complex structures through reuse. We
|
||
compare the peroformance of our modular approach with a monolithic
|
||
implementation on top of \yad, using Berkeley DB as a baseline.
|
||
|
||
|
||
\subsection{Runtime invariants}
|
||
|
||
In order to support recovery, a write-ahead-logging algorithm must
|
||
identify pages that {\em may} be written back to disk, and those that
|
||
{\em must} be written back to disk. \yad provides full support for
|
||
Steal/no-Force write ahead logging, due to its generally favorable
|
||
performance properties. ``Steal'' refers to the fact that pages may
|
||
be written back to disk before a transaction completes. ``No-Force''
|
||
means that a transaction may commit before the pages it modified are
|
||
written back to disk.
|
||
|
||
In a Steal/no-Force system, a page may be written to disk once the log
|
||
entries corresponding to the udpates it contains are written to the
|
||
log file. A page must be written to disk if the log file is full, and
|
||
the version of the page on disk is so old that deleting the beginning
|
||
of the log would lose redo information that may be needed at recovery.
|
||
|
||
Steal is desirable because it allows a single transaction to modify
|
||
more data than is present in memory. Also, it provides more
|
||
opportunities for the buffer manager to write pages back to disk.
|
||
Otherwise, in the face of concurrent transactions that all modify the
|
||
same page, it may never be legal to write the page back to disk. Of
|
||
course, if these problems would never come up in practice, an
|
||
application could opt for a no-Steal policy, possibly allowing it to
|
||
write undo information to the log file.
|
||
|
||
No-Force is often desirable for two reasons. First, forcing pages
|
||
modified by a transaction to disk can be extremely slow if the updates
|
||
are not near each other on disk. Second, if many transactions update
|
||
a page, Force could cause that page to be written once per transaction
|
||
that touched the page. However, a Force policy could reduce the
|
||
amount of redo information that must be written to the log file.
|
||
|
||
|
||
|
||
\subsection{Buffer manager policy}
|
||
|
||
Generally, write ahead logging algorithms ensure that the most recent
|
||
version of each memory-resident page is stored in the buffer manager,
|
||
and the most recent version of other pages is stored in the page file.
|
||
This allows the buffer manager to present a uniform view of the stored
|
||
data to the application. The buffer manager uses a cache replacement
|
||
policy (\yad currently uses LRU-2 by default) to decide which pages
|
||
should be written back to disk.
|
||
|
||
Section~\ref{oasys}, we will provide example where the most recent
|
||
version of application data is not managed by \yad at all, and
|
||
Section~\ref{zeroCopy} explains why efficiency may force certain
|
||
operations to bypass the buffer manager entirely.
|
||
|
||
\subsection{Atomic page file updates}
|
||
|
||
Most write ahead logging algorithms store an {\em LSN}, log sequence
|
||
number, on each page. The size and alignment of each page is chosen
|
||
so that it will be atomically updated, even if the system crashes.
|
||
Each operation performed on the page file is assigned a monotonically
|
||
increasing LSN. This way, when recovery begins, the system knows
|
||
which version of each page reached disk, and can undo or redo
|
||
operations accordingly. Operations do not need to be idempotent. For
|
||
example, a log entry could simply tell recovery to increment a value
|
||
on a page by some value, or to allocate a new record on the page. In
|
||
such cases, if the recovery algorithm does not know exactly which
|
||
version of a page it is dealing with, the operation could
|
||
inadvertantly be applied more than once, incrementing the value twice,
|
||
or double allocating a record.
|
||
|
||
However, if operations are idempotent, as is the case when pure
|
||
physical logging is used by an operation, we can remove the LSN field,
|
||
and have recovery conservatively assume that it is dealing with a page
|
||
that is potentially older than the one on disk. We call such pages
|
||
``LSN-free'' pages. While other systems use LSN-free
|
||
pages,~\cite{rvm} we observe that LSN-free pages can be stored
|
||
alongsize normal pages. Furthermore, efficient recovery and log
|
||
truncation require only minor modifications to our recovery algorithm.
|
||
In practice, this is implemented by providing a callback for LSN free
|
||
pages that allows the buffer manager to compute a conservative
|
||
estimate of the page's LSN whenever it is read from disk.
|
||
|
||
Section~\ref{zeroCopy} explains how these two observations led us to
|
||
approaches for recoverable virtual memory, and large object data that
|
||
we believe will have significant advantages when compared to existing
|
||
systems.
|
||
|
||
|
||
\subsection{Concurrent transactions}
|
||
|
||
So far, we have glossed over the behavior of our system when multiple
|
||
transactions execute concurrently. To understand the problems that
|
||
can arise when multiple transactions run concurrently, consider what
|
||
would happen if one transaction, A, rearranged the layout of a data
|
||
structure. Next, assume a second transaction, B modified that
|
||
structure, and then A aborted. When A rolls back, its UNDO entries
|
||
will undo the rearrangment that it made to the data structure, without
|
||
regard to B's modifications. This is likely to cause corruption.
|
||
|
||
Two common solutions to this problem are ``total isolation'' and
|
||
``nested top actions.'' Total isolation simply prevents any
|
||
transaction from accessing a data structure that has been modified by
|
||
another in-progress transaction. An application can achieve this
|
||
using its own concurrency control mechanisms to implement deadlock
|
||
avoidance, or by obtaining a commit duration lock on each data
|
||
structure that it modifies, and cope with the possibility that its
|
||
transactions may deadlock. Other approaches to the problem include
|
||
{\em cascading aborts}, where transactions abort if they make
|
||
modifications that rely upon modifications performed by aborted
|
||
transactions, and careful ordering of writes with custom recovery-time
|
||
logic to deal with potential inconsistencies. Because nested top
|
||
actions are easy to use, and fairly general, \yad contains operations
|
||
that implement nested top actions. \yad's nested top actions may be
|
||
used following these three steps:
|
||
|
||
\begin{enumerate}
|
||
\item Wrap a mutex around each operation. If this is done with care,
|
||
it may be possible to use finer grained mutexes.
|
||
\item Define a logical UNDO for each operation (rather than just using
|
||
a set of page-level UNDO's). For example, this is easy for a
|
||
hashtable; the UNDO for an {\em insert} is {\em remove}.
|
||
\item For mutating operations, (not read-only), add a ``begin nested
|
||
top action'' right after the mutex acquisition, and a ``commit
|
||
nested top action''right before the mutex is required.
|
||
\end{enumerate}
|
||
|
||
If the transaction that encloses the operation aborts, the logical
|
||
undo will {\em compensate} for its effects, leaving the structural
|
||
changes intact. Note that this recipe does not ensure transactional
|
||
consistency and is largely orthoganol to the use of a lock manager.
|
||
|
||
We have found that it is easy to protect operations that make
|
||
structural changes to data structures with nested top actions, and use
|
||
them throughout our default data structure implementations, although
|
||
\yad does not preclude the use of more complex schemes that lead to
|
||
higher concurrency.
|
||
|
||
\subsection{Isolation}
|
||
|
||
\yad distinguishes between {\em latches} and {\em locks}. A latch
|
||
corresponds to a operating system mutex, and is held for a short
|
||
period of time. All of \yad's default data structures use latches and
|
||
the 2PL deadlock avoidance scheme~\cite{twoPhaseLocking}. This allows multithreaded code to treat
|
||
\yad as a normal, reentrant data structure library. Applications that
|
||
want conventional transactional isolation, (eg: serializability), may
|
||
make use of a lock manager.
|
||
|
||
\subsection{Recovery and durability}
|
||
|
||
\yad makes use of the same basic recovery strategy as existing
|
||
write-ahead-logging schemes such as ARIES. Recovery consists of three
|
||
stages, {\em analysis}, {\em redo}, and {\em undo}. Analysis is
|
||
essentially a performance optimization, and makes use of information
|
||
left during forward operation to reduce the cost of redo and undo. It
|
||
also decides which transactions committed, and which aborted. The
|
||
redo phase iterates over the log, applying the redo function of each
|
||
logged operation if necessary. Once the log has been played forward,
|
||
the page file and buffer manager are in the same conceptual state they
|
||
were in at crash. The undo phase simply aborts each transaction that
|
||
does not have a commit entry, exactly as it would during normal
|
||
operation.
|
||
|
||
From the applications perspective, this process is interesting for a
|
||
number of reasons. First, if full transactional durability is
|
||
unneeded, the log can be flushed to disk less frequently, improving
|
||
performance. In fact, \yad allows applications to store the
|
||
transaction log in memory, reducing disk activity at the expense of
|
||
recovery. We are in the process of optimizing the system to handle
|
||
fully in-memory workloads efficiently.
|
||
|
||
\subsection{Summary of write ahead logging}
|
||
This section provided an extremely brief overview of
|
||
write-ahead-logging protocols. While the extensions that it proposes
|
||
require a fair amount of knowledge about transactional logging
|
||
schemes, our initial experience customizing the system for various
|
||
applications is positive. We believe that the time spent customizing
|
||
the library is less than amount of time that it would take to work
|
||
around typical problems with existing transactional storage systems.
|
||
However, we do not yet have a good understanding of the testing and
|
||
reliability issues that arise in practice as the system is modified in
|
||
this fashion.
|
||
|
||
\section{Extensions}
|
||
|
||
This section desribes proof-of-concept extensions to \yad.
|
||
Performance figures accompany the extensions that we have implemented.
|
||
We discuss existing approaches to the systems presented here when
|
||
appropriate.
|
||
|
||
\subsection{Adding log operations}
|
||
\begin{figure}
|
||
\includegraphics[%
|
||
width=1\columnwidth]{figs/structure.pdf}
|
||
\caption{\sf\label{fig:structure} The portions of \yad that new operations interact with directly.}
|
||
\end{figure}
|
||
\yad allows application developers to easily add new operations to the
|
||
system. Many of the customizations described below can be implemented
|
||
using custom log operations. In this section, we desribe how to add a
|
||
``typical'' Steal/no-Force operation that supports concurrent
|
||
transactions, full physiological logging, and per-page LSN's. Such
|
||
opeartions are typical of high-performance commercial database
|
||
engines.
|
||
|
||
As we mentioned above, \yad operations must implement a number of
|
||
functions. Figure~\ref{yadArch} describes the environment that
|
||
schedules and invokes these functions. The first step in implementing
|
||
a new set of log interfaces is to decide upon interface that these log
|
||
interfaces will export to callers outside of \yad.
|
||
|
||
These interfaces are implemented by the Wrapper Functions and Read
|
||
only access methods in Figure~\ref{yadArch}. Wrapper functions that
|
||
modify the state of the database package any information that will be
|
||
needed for undo or redo into a data format of its choosing. This data
|
||
structure, and an opcode associated with the type of the new
|
||
operation, are passed into Tupdate(), which copies its arguments to
|
||
the log, and then passes its arguments into the operation's REDO
|
||
function.
|
||
|
||
REDO modifies the page file, or takes some other action directly. It
|
||
is essentially an iterpreter for the log entries it is associated
|
||
with. UNDO works analagously, but is invoked when an operation must
|
||
be undone (usually due to an aborted transaction, or during recovery).
|
||
This general pattern is quite general, and applies in many cases. In
|
||
order to implement a ``typical'' operation, the operations
|
||
implementation must obey a few more invariants:
|
||
|
||
\begin{itemize}
|
||
\item Pages should only be updated inside REDO and UNDO functions.
|
||
\item Page updates atomically update page LSN's by pinning the page.
|
||
\item If the data seen by a wrapper function must match data seen
|
||
during REDO, then the wrapper should use a latch to protect against
|
||
concurrent attempts to update the sensitive data (and against
|
||
concurrent attempts to allocate log entries that update the data).
|
||
\item Nested top actions (and logical undo), or ``big locks'' (which
|
||
reduce concurrency) should be used to implement multi-page updates.
|
||
\end{itemize}
|
||
|
||
\subsection{Linear hash table}
|
||
\begin{figure}[t]
|
||
\includegraphics[%
|
||
width=1\columnwidth]{figs/bulk-load.pdf}
|
||
%\includegraphics[%
|
||
% width=1\columnwidth]{bulk-load-raw.pdf}
|
||
%\vspace{-30pt}
|
||
\caption{\sf\label{fig:BULK_LOAD} Performance of \yad and Berkeley DB hashtable implementations. The
|
||
test is run as a single transaction, minimizing overheads due to synchronous log writes.}
|
||
\end{figure}
|
||
\begin{figure}[t]
|
||
%\hspace*{18pt}
|
||
%\includegraphics[%
|
||
% width=1\columnwidth]{tps-new.pdf}
|
||
\includegraphics[%
|
||
width=3.25in]{figs/tps-extended.pdf}
|
||
%\vspace{-36pt}
|
||
\caption{\sf\label{fig:TPS} High concurrency performance of Berkeley DB and \yad. We were unable to get Berkeley DB to work correctly with more than 50 threads. (See text)
|
||
}
|
||
\end{figure}
|
||
|
||
Although the beginning of this paper describes the limitations of
|
||
physical database models and relational storage systems in great
|
||
detail, these systems are the basis of most common transactional
|
||
storage routines. Therefore, we implement key-based storage, and a
|
||
primititve form of linksets in this section. We argue that obtaining
|
||
obtaining reasonable performance in such a system under \yad is
|
||
straightforward, and compare a simple hash table to a hand-tuned (not
|
||
straightforward) hash table, and Berkeley DB's implementation.
|
||
|
||
The simple hash table uses nested top actions to atomically update its
|
||
internal structure. It is based on a linear hash function, allowing
|
||
it to incrementally grow its buffer list. It is based on a number of
|
||
modular subcomponents, notably a growable array of fixed length
|
||
entries, and the user's choice of two different linked list
|
||
implementations. The hand-tuned hashtable also uses a {\em linear} hash
|
||
function,~\cite{lht} but is monolithic, and uses carefully ordered writes to
|
||
reduce log bandwidth, and other runtime overhead. Berkeley DB's
|
||
hashtable is a popular, commonly deployed implementation, and serves
|
||
as a baseline for our experiements.
|
||
|
||
Both of our hashtables outperform Berkeley DB on a workload that
|
||
bulkloads the tables by repeatedly inserting key, value pairs into
|
||
them. We do not claim that our partial implementation of \yad
|
||
generally outperforms Berkeley DB, or that it is a robust alternative
|
||
to Berkeley DB. Instead, this test shows that \yad is comparable to
|
||
existing systems, and that its modular design does not introduce gross
|
||
inefficiencies at runtime.
|
||
|
||
The comparison between our two hash implementations is more
|
||
enlightening. The performance of the simple hash table shows that
|
||
quick, straightfoward datastructure implementations composed from
|
||
simpler structures behave reasonably well in \yad. The hand-tuned
|
||
implementation shows that \yad allows application developers to
|
||
optimize the primitives they build their applications upon. In the
|
||
best case, past systems allowed application developers to providing
|
||
hints to improve performance. In the worst case, a developer would be
|
||
forced to redesign the application to avoid sub-optimal properties of
|
||
the transactional data structure implementation.
|
||
|
||
Figure~\ref{lhtThread} describes performance of the two systems under
|
||
highly concurrent workloads. For this test, we used the simple
|
||
(unoptimized) hash table, since we are interested in the performance a
|
||
clean, modular data structure that a typical system implementor would
|
||
be likely to produce, not the performance of our own highly tuned,
|
||
monolithic, implementations.
|
||
|
||
Both Berekely DB and \yad can service concurrent calls to commit with
|
||
a single synchronous I/O.\endnote{The multi-threaded benchmarks
|
||
presented here were performed using an ext3 filesystem, as high
|
||
concurrency caused both Berkeley DB and \yad to behave unpredictably
|
||
when reiserfs was used. However, \yad's multi-threaded throughput
|
||
was significantly better that Berkeley DB's under both systems.}
|
||
\yad scaled quite well, delivering over 6000 transactions per
|
||
second,\endnote{This test was run without lock managers, so the
|
||
transactions obeyed the A, C, and D properties. Since each
|
||
transaction performed exactly one hashtable write and no reads, they
|
||
obeyed I (isolation) in a trivial sense.} and provided roughly
|
||
double Berkeley DB's throughput (up to 50 threads). We do not report
|
||
the data here, but we implemented a simple load generator that makes
|
||
use of a fixed pool of threads with a fixed think time. We found that
|
||
the latency of Berkeley DB and \yad were similar, addressing concerns
|
||
that \yad simply trades latency for throughput during the concurrency
|
||
benchmark.
|
||
|
||
\subsection{Object serialization}
|
||
|
||
\begin{figure*}[t!]
|
||
\includegraphics[width=3.3in]{figs/object-diff.pdf}
|
||
\hspace{.3in}
|
||
\includegraphics[width=3.3in]{figs/mem-pressure.pdf}
|
||
\vspace{-.15in}
|
||
\caption{\sf \label{fig:OASYS}
|
||
The effect of \yad object serialization optimizations under low and high memory pressure.}
|
||
\end{figure*}
|
||
|
||
Numerous schemes are used for object serialization. Support for two
|
||
different styles of object serialization have been eimplemented in
|
||
\yad. The first, pobj, provided transactional updates to objects in
|
||
Titanium, a Java variant. It transparently loaded and persisted
|
||
entire graphs of objects.
|
||
|
||
The second variant was built on top of a generic C++ object
|
||
serialization library, \oasys. \oasys makes use of pluggable storage
|
||
modules to actually implement persistant storage, and includes plugins
|
||
for Berkeley DB and MySQL. This section will describe how the \yad's
|
||
\oasys plugin reduces the runtime serialization/deserialization cpu
|
||
overhead of write intensive workloads, while using half as much system
|
||
memory as the other two systems.
|
||
|
||
We present three variants of \yad here. The first treats \yad like
|
||
Berkeley DB. The second customizes the behavior of the buffer
|
||
manager. Instead of maintaining an up-to-date version of each object
|
||
in the buffer manager or page file, it allows the buffer manager's
|
||
view of live application objects to become stale. This is safe since
|
||
the system is always able to reconstruct the appropriate page entry
|
||
form the live copy of the object.
|
||
|
||
The reason it would be difficult to do this with Berkeley DB is that
|
||
we still need to generate log entries as the object is being updated.
|
||
Otherwise, commit would not be durable, and the application would be
|
||
unable to abort() transactions. Even if we decided to disallow
|
||
application aborts, we would still need to write log entries
|
||
committing. This would cause Berekley DB to write data back to the
|
||
page file, increasing the working set of the program, and increasing
|
||
disk activity.
|
||
|
||
Under \yad, we implemented this optimization by adding two new
|
||
operations, update(), which only updates the log, and flush(), which
|
||
updates the page file. We decrease the size of the page file, so
|
||
flush() is likely to incur disk overhead. However, we have roughly
|
||
doubled the number of objects that are cached in memory, and expect
|
||
flush() to be called relatively infrequently.
|
||
|
||
The third \yad plugin to \oasys incorporated all of the updates of the
|
||
second, but arranged to only the changed portions of objects to the
|
||
log.
|
||
|
||
Figure~\ref{objectSerialization} presents the performance of the three
|
||
\yad optimizations, and the \oasys plugins implemented on top of other
|
||
systems. As we can see, \yad performs better than the baseline
|
||
systems. More interestingly, in non-memory bound systems, the
|
||
optimizations nearly double \yad's performance, and we see that in the
|
||
memory-bound setup, update/flush indeed improves memory utilization.
|
||
|
||
|
||
\subsection{Manipulation of logical log entries}
|
||
|
||
\begin{figure}
|
||
\includegraphics[width=1\columnwidth]{figs/graph-traversal.pdf}
|
||
\vspace{-24pt}
|
||
\caption{\sf\label{fig:multiplexor} Because pages are independent, we
|
||
can reorder requests among different pages. Using a log demultiplexer,
|
||
we partition requests into independent queues, which can be
|
||
handled in any order, improving locality and merging opportunities.}
|
||
\end{figure}
|
||
\begin{figure}[t]
|
||
\includegraphics[width=3.3in]{figs/oo7.pdf}
|
||
\vspace{-15pt}
|
||
\caption{\sf\label{fig:oo7} oo7 benchmark style graph traversal. The optimization performs well due to the presence of non-local nodes.}
|
||
\end{figure}
|
||
|
||
\begin{figure}[t]
|
||
\includegraphics[width=3.3in]{figs/trans-closure-hotset.pdf}
|
||
\vspace{-12pt}
|
||
\caption{\sf\label{fig:hotGraph} Hot set based graph traversal for random graphs with out-degrees of 3 and 9. Here
|
||
we see that the multiplexer helps when the graph has poor locality.
|
||
However, in the cases where depth first search performs well, the
|
||
reordering is inexpensive.}
|
||
\end{figure}
|
||
|
||
Database optimizers operate over relational algebra expressions that
|
||
will correspond to sequence of logical operations at runtime. \yad
|
||
does not support query languages, relational algebra, or other general
|
||
purpose primitves.
|
||
|
||
However, it does include an extendible logging infrastructure, and any
|
||
operations that make user of physiological logging implicitly
|
||
implement UNDO (and often REDO) functions that interpret logical
|
||
operations.
|
||
|
||
Logical operations often have some nice properties that this section
|
||
will exploit. Because they can be invoked at arbitrary times in the
|
||
future, they tend to be independent of the database's physical state.
|
||
They tend to be inverses of operations that programmer's understand.
|
||
If each method in the API exposed to the programmer is the inverse of
|
||
some other method in the API, then each logical operation corresponds
|
||
to a method the programmer can manually invoke.
|
||
|
||
Because of this, application developers can easily determine whether
|
||
logical operations may safely be reordered, transformed, or even
|
||
dropped from the stream of requests that \yad is processing. Even
|
||
better, if requests can be partitioned in a natural way, load
|
||
balancing can be implemented by spliting requests across many nodes.
|
||
Similarly, a node can easily service streams of requests from multiple
|
||
nodes by combining them into a single log, and processing the log
|
||
using operaiton implementations. Furthermore, application-specific
|
||
procedures that are analagous to standard relational algebra methods
|
||
(join, project and select) could be used to efficiently transform the data
|
||
before it reaches the page file, while it is layed out sequentially
|
||
in memory.
|
||
|
||
Note that read-only operations do not necessarily generate log
|
||
entries. Therefore, applications may need to implement custom
|
||
operations to make use of the ideas in this section.
|
||
|
||
Although \yad has rudimentary support for a two-phase commit based
|
||
cluster hash table, we have not yet implemented a logical log based
|
||
networking primitives. Therefore, we implemented some of these ideas
|
||
in a single node configuration in order to increase request locality
|
||
during the traversal of a random graph. The graph traversal system
|
||
takes a sequence of (read) requests, and partitions them using some
|
||
function. It then proceses each partition in isolation from the
|
||
others. We considered two partitioning functions. The first, which
|
||
is really only of interested in the distributed case, partitions the
|
||
requests according to the hash of the node id they refer to. This
|
||
would allow us to balance the graph traversal across many nodes. (We
|
||
expect the early phases of such a traversal to be bandwidth, not
|
||
latency limited, as each node would stream large sequences of
|
||
asynchronous requests to the other nodes.)
|
||
|
||
The second partitioning function, which was used to produce
|
||
Figure~\ref{hotset} partitions requests by their position in the page
|
||
file. When the graph has good locality, a normal depth first search
|
||
traversal and the prioritized traversal perform well. As locality
|
||
decreases, the partitioned traversal algorithm's performance degrades
|
||
less than the naive traversal.
|
||
|
||
**TODO This really needs more experimental setup... look at older draft!**
|
||
|
||
\subsection{LSN-Free pages}
|
||
|
||
In Section~\ref{todo}, we describe how operations can avoid recording
|
||
LSN's on the pages they modify. Essentially, opeartions that make use
|
||
of purely physical logging need not heed page boundaries, as
|
||
physiological operations must. Recall that purely physical logging
|
||
interacts poorly with concurrent transactions that modify the same
|
||
data structures or pages, so LSN-Free pages are not applicable in all
|
||
situations.
|
||
|
||
Consider the retreival of a large (page spanning) object stored on
|
||
pages that contain LSN's. The object's data will not be contiguous.
|
||
Therefore, in order to retrive the object, the transaction system must
|
||
load the pages contained on disk into memory, allocate buffer space to
|
||
allow the object to be read, and perform a byte-by-byte copy of the
|
||
portions of the pages that contain the large object's data. Compare
|
||
this approach to a modern filesystem, which allows applications to
|
||
perform a DMA copy of the data into memory, avoiding the expensive
|
||
byte-by-byte copy of the data, and allowing the CPU to be used for
|
||
more productive purposes. Furthermore, modern operating systems allow
|
||
network services to use DMA and ethernet adaptor hardware to read data
|
||
from disk, and send it over a network socket without passing it
|
||
through the CPU. Again, this frees the CPU, allowing it to perform
|
||
other tasks.
|
||
|
||
We beleive that LSN free pages will allow reads to make use of such
|
||
optimizations in a straightforward fashion. Zero copy writes could be
|
||
performed by performing a DMA write to a portion of the log file.
|
||
However, doing this complicates log truncation, and does not address
|
||
the problem of updating the page file. We suspect that contributions
|
||
from the log based filesystem literature can address these problems in
|
||
a straightforward fashion.
|
||
|
||
Finally, RVM, recoverable virtual memory, made use of LSN-free pages
|
||
so that it could use mmap() to map portions of the page file into
|
||
application memory. However, without support for logical log entries
|
||
and nested top actions, it would be difficult to implement a
|
||
concurrent, durable data structure using RVM. We plan to add RVM
|
||
style transactional memory to \yad in a way that is compatible with
|
||
fully concurrent collections such as hash tables and tree structures.
|
||
|
||
\section{Conclusion}
|
||
|
||
\section{Acknowledgements}
|
||
|
||
\section{Availability}
|
||
|
||
Additional information, and \yad's source code is available at:
|
||
|
||
\begin{center}
|
||
{\tt http://\yad.sourceforge.net/}
|
||
\end{center}
|
||
|
||
{\footnotesize \bibliographystyle{acm}
|
||
\nocite{*}
|
||
\bibliography{LLADD}}
|
||
|
||
\theendnotes
|
||
|
||
\end{document}
|
||
|
||
|
||
|
||
|
||
|
||
|
||
|