Added more LLADD details; it probably has grammer mistakes now.
This commit is contained in:
parent
66801e3091
commit
f7ce3b70a6
1 changed files with 110 additions and 34 deletions
|
@ -1,4 +1,3 @@
|
|||
|
||||
Russell Sears
|
||||
Eric Brewer
|
||||
|
||||
|
@ -11,30 +10,96 @@ geared toward specific workloads and data layouts such as those
|
|||
traditionally associated with SQL. Lower level implementations such
|
||||
as Berkeley DB handle a wider variety of workloads and are built in a
|
||||
modular fashion. However, they do not provide APIs to allow
|
||||
applications to build upon or modify low level policies such as
|
||||
allocation strategies, page layout or details of the recovery
|
||||
algorithm. Furthermore, data structure implementations are typically
|
||||
not broken into separable, public API's, encouraging a "from scratch"
|
||||
applications to build upon and modify low level policies such as
|
||||
allocation strategies, page layout or details of recovery semantics.
|
||||
Furthermore, data structure implementations are typically
|
||||
not broken into separable, public APIs, encouraging a "from scratch"
|
||||
approach to the implementation of extensions.
|
||||
|
||||
Contrast this to the handling of data structures within modern object
|
||||
oriented programming languages such as Java or C++ that provide a
|
||||
large number of data storage algorithm implementations. Such
|
||||
oriented programming languages such as Java or C++. Such languages typically provide a
|
||||
large number of data storage algorithm implementations. These
|
||||
structures may be used interchangeably with application-specific data
|
||||
collections, and collection implementations can be composed into more
|
||||
sophisticated data structures.
|
||||
|
||||
We have implemented LLADD (/yad/), an extensible transactional storage
|
||||
implementation that takes a composable and layered approach to
|
||||
transactional storage. In other work, we show that its performance on
|
||||
traditional workloads is competitive with existing systems and show
|
||||
significant increases in throughput and memory utilization on
|
||||
specialized workloads.[XXX]
|
||||
library that takes a composable and layered approach to
|
||||
transactional storage. Below, we present some of the high level
|
||||
features and performance characteristics of this system and discuss
|
||||
our plans to extend the system into distributed domains. Finally we
|
||||
introduce our current research focus, the application of automated
|
||||
program verification and optimization techniques to application specific extensions. Such
|
||||
techniques should significantly enhance the usability and performance
|
||||
of our system.
|
||||
|
||||
We further argue that because of its natural integration into standard
|
||||
system software development practices our library can be naturally
|
||||
extended into networked and distributed domains. Typical
|
||||
write-ahead-logging protocols implicitly implement machine
|
||||
Overview of the LLADD Architecture
|
||||
|
||||
General purpose transactional storage systems are extremely complex
|
||||
and only handle certain types of workloads efficiently. However, new
|
||||
types of applications and workloads are introduced on a regular basis.
|
||||
This results in the implementation of specialized, ad-hoc data storage
|
||||
systems from scratch, wasting resources and preventing code reuse.
|
||||
|
||||
Instead of developing a set of general purpose data structures that
|
||||
attempt to behave well across many workloads, we have implemented a
|
||||
lower level API that makes it easy for application designers to
|
||||
implement specialized data structures. Essentially, we have
|
||||
implemented a modern, extensible navigational database system. We
|
||||
believe that this system will support modern development practices and
|
||||
address new applications that are evolving too quickly to allow
|
||||
appropriate general-purpose solutions to be developed.
|
||||
|
||||
The library is based upon an extensible version of ARIES but does not
|
||||
hard-code details such as page format or data structure implementation.
|
||||
It provides a number of "operation" implementations which consist of
|
||||
redo/undo implementations that apply log entries and wrapper
|
||||
functions that produce log entries.
|
||||
During normal forward operations, page file writes are processed by
|
||||
applying redo entries from the log. Other than the invocation of code
|
||||
that allocates and writes log entries there is no difference between
|
||||
the redo phase of recovery and normal forward operation. This reduces
|
||||
the amount of code that must be developed in order to implement new
|
||||
data structures and page layouts.
|
||||
|
||||
Of course, LLADD ships with a number of default data structures and
|
||||
layouts, ranging from byte-level page layouts to a linear hashtable
|
||||
that was built using high-level reusable components. The
|
||||
hashtable is implemented on top of a resizable array and a
|
||||
locality preserving linked list implementation.
|
||||
|
||||
Unlike existing solutions, we view data structure implementations from
|
||||
a reusability standpoint, allowing and encouraging application
|
||||
developers to compose existing transactional operations into
|
||||
application-specific data structures.
|
||||
|
||||
In other work, we have shown that the system is competitive with
|
||||
Berkeley DB on traditional (hashtable based) workloads, and have shown
|
||||
significant performance improvements for less conventional workloads
|
||||
including custom data structure implementations, graph traversal
|
||||
algorithms and transactional object persistence workloads.
|
||||
|
||||
We showed a 2-3x performance improvement over Berkeley DB on object
|
||||
persistence across our benchmarks, and a 3-4x improvement over an
|
||||
in-process version of MySQL with the InnoDB backend. (A traditional,
|
||||
IPC-based MySQL benchmark was prohibitively slow and InnoDB provided
|
||||
the best performance among MySQL's durable storage managers.)
|
||||
|
||||
Furthermore, our system only keeps one copy of each object in memory
|
||||
at a time, while most existing systems keep a second copy in the
|
||||
transactional system's page cache (and possibly a third copy in
|
||||
operating system cache). Therefore, our system can cache roughly
|
||||
twice as many objects in memory as the systems we compared it to. We leave systematic
|
||||
performance tuning of LLADD to future work, and believe that further
|
||||
optimizations would
|
||||
improve our performance on these benchmarks significantly.
|
||||
|
||||
LLADD's customizability provides superior performance over existing,
|
||||
complex systems. Because of its natural
|
||||
integration into standard system software development practices, we think that LLADD
|
||||
can be naturally extended into networked and distributed domains.
|
||||
|
||||
For example, typical write-ahead-logging protocols implicitly implement machine
|
||||
independent, reorderable log entries in order to implement logical
|
||||
undo. These two properties have been crucial in past system software
|
||||
designs, including data replication, distribution, and conflict
|
||||
|
@ -43,19 +108,20 @@ logical redo log as an application-level primitive, and to explore
|
|||
system designs that leverage these primitives.
|
||||
|
||||
However, our approach assumes that application developers will
|
||||
correctly implement new transactional structures even though these
|
||||
data structures are notoriously difficult to implement correctly. In
|
||||
this work we present our current attempts to address these concerns.
|
||||
implement high performance transactional data structures. This
|
||||
is a big assumption, as these
|
||||
data structures are notoriously difficult to implement correctly.
|
||||
Our current research attempts to address these concerns.
|
||||
|
||||
For such infrastructure to be generally useful, however, the
|
||||
For our infrastructure to be generally useful the
|
||||
functionality that it provides should be efficient, reliable and
|
||||
applicable to new application domains. We believe that ease of
|
||||
development is a prerequisite to our other goals.
|
||||
applicable to new application domains. We believe that improvements
|
||||
to the development process can address each of these goals.
|
||||
|
||||
Application developers typically have a limited amount of time to
|
||||
spend implementing and verifying application-specific storage
|
||||
extensions, and bugs in these extensions affect data durability.
|
||||
While the underlying data structure algorithms tend to be simple and
|
||||
extensions, but bugs in these extensions have dire consequences.
|
||||
Also, while data structure algorithms tend to be simple and
|
||||
easily understood, performance tuning and verification of
|
||||
implementation correctness is extremely difficult.
|
||||
|
||||
|
@ -75,25 +141,26 @@ Existing work in the static-analysis community has verified that
|
|||
device driver implementations correctly adhere to complex operating
|
||||
system kernel locking schemes[SLAM]. If we formalize LLADD's latching
|
||||
and logging APIs, we believe that analyses such as these will be
|
||||
directly applicable, and allow us to verify that data structure
|
||||
behavior during recovery is equivalent to its behavior on each prefix
|
||||
of the log produced during normal forward operation.
|
||||
directly applicable, allowing us to verify that data structure
|
||||
behavior during recovery is equivalent to the behavior that would
|
||||
result if an abort() was issued on each prefix of the log that is
|
||||
generated during normal forward operation.
|
||||
|
||||
By using coarse (one latch per logical operation) latching, we can
|
||||
drastically reduce the size of this space, allowing conventional
|
||||
state-state based search techniques (such as randomized or exhaustive
|
||||
state-space searches, or simple unit testing techniques) to be
|
||||
state-space searches, or even standard unit testing techniques) to be
|
||||
practical. It has been shown that such coarse grained latching can
|
||||
yield high performance concurrent data structures if
|
||||
semantics-preserving optimizations such as page prefetching are
|
||||
applied[ARIES/IM].
|
||||
|
||||
A separate approach toward static analysis of LLADD extensions
|
||||
involves compiler optimization techniques. Software built on top of
|
||||
layered API's frequently makes repeated calls to low level functions
|
||||
A separate approach to the static analysis of LLADD extensions
|
||||
uses compiler optimization techniques. Software built on top of
|
||||
layered APIs frequently makes repeated calls to low level functions
|
||||
that must repeat work. A common example in LLADD involves loops over
|
||||
data with good locality in the page file. The vast majority of the
|
||||
time, these loops call high level API's that needlessly pin and unpin
|
||||
time, these loops call high level APIs that needlessly pin and unpin
|
||||
the same underlying data.
|
||||
|
||||
The code for each of these high level API calls could be copied into
|
||||
|
@ -107,11 +174,20 @@ elimination solve an analogous problem to remove unnecessary algebraic
|
|||
computations. We hope to extend such techniques to reduce the number
|
||||
of buffer manager and locking calls made by existing code at runtime.
|
||||
|
||||
We suspect that similar optimization techniques are applicable to
|
||||
application code. Because local LLADD calls are simply normal
|
||||
function calls, it may even be possible to push the optimizations
|
||||
mentioned above up into application code, providing a class of
|
||||
optimizations that would be very difficult to replicate with existing
|
||||
transactional storage systems. However, combining this technique with
|
||||
distributed storage systems may raise a number of interesting
|
||||
questions.
|
||||
|
||||
Our implementation of LLADD is still unstable and inappropriate for
|
||||
use on important data. We hope to validate our static analysis tools
|
||||
by incorporating them into LLADD's development process as we increase
|
||||
the reliability and overall quality of our implementation and its
|
||||
API's.
|
||||
APIs.
|
||||
|
||||
LLADD provides a set of tools that allow applications to implement
|
||||
custom transactional data structures and page layouts. This avoids
|
||||
|
|
Loading…
Reference in a new issue