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@ -247,7 +247,7 @@ database models}.
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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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is chosen to support efficiently the set of mappings that are built on
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top of it.
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\diff{A conceptual mapping based on the relational model might
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@ -261,9 +261,13 @@ be more appropriate~\cite{molap}. Although both OLTP and OLAP databases are bas
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upon the relational model they make use of different physical models
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in order to serve different classes of applications.}
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\eab{need to expand the following and add evidence.}
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A key observation of this paper is that no known physical data model
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can efficiently support more than a small percentage of today's applications.
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\diff{ A basic claim of
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this paper is that no single known physical data model can efficiently
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support the wide range of conceptual mappings that are in use today.
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In addition to sets, objects, and XML, such a model would need
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to cover search engines, version-control systems, work-flow
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applications, and scientific computing, as examples.
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}
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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 transactional
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@ -275,13 +279,15 @@ structured physical model or abstract conceptual mappings.
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\subsection{Extensible transaction systems}
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\label{sec:otherDBs}
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This section contains discussion of transaction systems with goals
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\diff{This section contains discussion of transaction systems with goals
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similar to ours. Although these projects were successful in many
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respects, they fundamentally aimed to implement an extensible abstract
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data model, rather than take a bottom-up approach and allow
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applications to customize the physical model in order to support new
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high-level abstractions. In each case, this limits these systems to
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applications their physical models support well.\eab{expand this claim}
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respects, they fundamentally aimed to extend the range of their
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abstract data model, which in the end still has limited overall range.
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In contrast, \yad follows a bottom-up approach that enables can
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implement (in theory) any of these abstract models and their extensions.
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}
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\subsubsection{Extensible databases}
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@ -313,9 +319,8 @@ compiled. In today's object-relational database systems, new types
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are defined at runtime. Each approach has its advantages. However,
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both types of systems aim to extend a high-level data model with new
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abstract data types, and thus are quite limited in the range of new
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applications they support. In hindsight, it is not surprising that this kind of
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extensibility has had little impact on the range of applications
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we listed above. \rcs{This could be more clear. Perhaps ``... on applications that are not naturally supported by queries over sets of tuples, or other data items''?}
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applications they support, essentially queries over sets of a wider
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range of elements.
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\subsubsection{Transactional Programming Models}
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@ -331,7 +336,7 @@ high-level transactional interfaces.
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\eab{add Argus and Camelot}
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\eab{add Argus and Camelot; also we are getting pretty technical here -- maybe move some of this later???}
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\rcs{ I think Argus makes use of shadow copies for durability, and for
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in-memory transactions. A tree of shadow copies exists, and is handled as
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@ -455,9 +460,10 @@ platform that enables specialization and shares the effort required to build a f
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We agree with the motivations behind RISC databases and the goal
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of highly modular database implementations. In fact, we hope
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our system will mature to the point where it can support
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a competitive relational database. However this is
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not our primary goal, as we seek instead to enable a wider range of data management options.\eab{expand on ``wider''}
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our system will mature to the point where it can support a
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competitive relational database. However this is not our primary
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goal, which is to enable a wide range of transactional systems, and
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explore those applications that are a weaker fit for DMBSs.
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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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@ -617,8 +623,8 @@ However, Undo does write log entries. In order to prevent repeated
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crashes during recovery from causing the log to grow excessively, the
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entries that Undo writes tell future invocations of Undo to skip
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portions of the transaction that have already been undone. These log
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entries are usually called {\em Compensation Log Records (CLR's)}.
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Note that CLR's only cause Undo to skip log entries. Redo will apply
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entries are usually called {\em Compensation Log Records (CLRs)}.
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Note that CLRs only cause Undo to skip log entries. Redo will apply
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log entries protected by the CLR, guaranteeing that those updates are
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applied to the page file.
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