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http://www.byte.com/bmark/bmark.htm
----------------------------------------------------------------------------
BYTEmark
----------------------------------------------------------------------------
This is release 2 of BYTE Magazine's BYTEmark benchmark program (previously
known as BYTE's Native Mode Benchmarks). This document covers the Native
Mode (a.k.a. Algorithm Level) tests; benchmarks designed to expose the
capabilities of a system's CPU, FPU, and memory system. Another group of
benchmarks within the BYTEmark suite includes the Application Simulation
Benchmarks. They are detailed in a separate document. [NOTE: The
documentation for the Application simulation benchmarks should appear before
the end of March, 95. -- RG].
The Tests
The Native Mode portion of the BYTEmark consists of a number of well-known
algorithms; some BYTE has used before in earlier versions of the benchmark,
others are new. The complete suite consists of 10 tests:
Numeric sort - Sorts an array of 32-bit integers.
String sort - Sorts an array of strings of arbitrary length.
Bitfield - Executes a variety of bit manipulation functions.
Emulated floating-point - A small software floating-point package.
Fourier coefficients - A numerical analysis routine for calculating series
approximations of waveforms.
Assignment algorithm - A well-known task allocation algorithm.
Huffman compression - A well-known text and graphics compression algorithm.
IDEA encryption - A relatively new block cipher algorithm.
Neural Net - A small but functional back-propagation network simulator.
LU Decomposition - A robust algorithm for solving linear equations.
A more complete description of each test can be found in later sections of
this document.
BYTE built the BYTEmark with the multiplatform world foremost in mind. There
were, of course, other considerations that we kept high on the list:
Real-world algorithms. The algorithms should actually do something. Previous
benchmarks often moved gobs of bytes from one point to another, added or
subtracted piles and piles of numbers, or (in some cases) actually executed
NOP instructions. We should not belittle those tests of yesterday, they had
their place. However, we think it better that tests be based on activities
that are more complex in nature.
Easy to port. All the benchmarks are written in "vanilla" ANSI C. This
provides us with the best chance of moving them quickly and accurately to
new processors and operating systems as they appear. It also simplifies
maintenance.
This means that as new 64-bit (and, perhaps, 128-bit) processors appear, the
benchmarks can test them as soon as a compiler is available.
Comprehensive. The algorithms were derived from a variety of sources. Some
are routines that BYTE had been using for some time. Others are routines
derived from well-known texts in the computer science world. Furthermore,
the algorithms differ in structure. Some simply "walk" sequentially through
one-dimensional arrays. Others build and manipulate two-dimensional arrays.
Finally, some benchmarks are "integer" tests, while others exercise the
floating-point coprocessor (if one is available).
Scalable. We wanted these benchmarks to be useful across as wide a variety
of systems as possible. We also wanted to give them a lifetime beyond the
next wave of new processors.
To that end, we incorporated "dynamic workload adjustment." A complete
description of this appears in a later section. In a nutshell, this allows
the tests to "expand or contract" depending on the capabilities of the
system under test, all the while providing consistent results so that fair
and accurate comparisons are possible.
Honesty In Advertising
We'd be lying if we said that the BYTEmark was all the benchmarking that
anyone would ever need to run on a system. It would be equally inaccurate to
suggest that the tests are completely free of inadequacies. There are many
things the tests do not do, there are shortcomings, and there are problems.
BYTE will continue to improve the BYTEmark. The source code is freely
available, and we encourage vendors and users to examine the routines and
provide us with their feedback. In this way, we assure fairness,
comprehensiveness, and accuracy.
Still, as we mentioned, there are some shortcomings. Here are those we
consider the most significant. Keep them in mind as you examine the results
of the benchmarks now and in the future.
At the mercy of C compilers. Being written in ANSI C, the benchmark program
is highly portable. This is a reflection of the "world we live in." If this
were a one-processor world, we might stand a chance at hand-crafting a
benchmark in assembly language. (At one time, that's exactly what BYTE did.)
Not today, no way.
The upshot is that the benchmarks must be compiled. For broadest coverage,
we selected ANSI C. And when they're compiled, the resulting executable's
performance can be highly dependent on the capabilities of the C compiler.
Today's benchmark results can be blown out of the water tomorrow if someone
new enters the scene with an optimizing strategy that outperforms existing
competition.
This concern is not easily waved off. It will require you to keep careful
track of compiler version and optimization switches. As BYTE builds its
database of benchmark results, version number and switch setting will become
an integral part of that data. This will be true for published information
as well, so that you can make comparisons fairly and accurately. BYTE will
control the distribution of test results so that all relevant compiler
information is attached to the data.
As a faint justification -- for those who think this situation results in
"polluted" tests -- we should point out that we are in the same boat as all
the other developers (at least, all those using C compilers -- and that's
quite a sizeable group). If the only C compilers for a given system happen
to be poor ones, everyone suffers. It's a fact that a given platform's
ultimate potential depends as much on the development software available as
on the technical achievements of the hardware design.
It's just CPU and FPU. It's very tempting to try to capture the performance
of a machine in a single number. That has never been possible -- though it's
been tried a lot -- and the gap between that ideal and reality will forever
widen.
These benchmarks are meant to expose the theoretical upper limit of the CPU,
FPU, and memory architecture of a system. They cannot measure video, disk,
or network throughput (those are the domains of a different set of
benchmarks). You should, therefore, use the results of these tests as part,
not all, of any evaluation of a system.
Single threaded. Currently, each benchmark test uses only a single execution
thread. It's unlikely that you'll find any modern operating system that does
not have some multitasking component. How a system "scales" as more tasks
are run simultaneously is an effect that the current benchmarks cannot
explore.
BYTE is working on a future version of the tests that will solve this
problem.
The tests are synthetic. This quite reasonable argument is based on the fact
that people don't run benchmarks for a living, they run applications.
Consequently, the only true measure of a system is how well it performs
whatever applications you will be running. This, in fact, is the philosophy
behind the BAPCo benchmarks.
This is not a point with which we would disagree. BYTE regularly makes use
of a variety of application benchmarks. None of this suggests, however, that
the BYTEmark benchmarks serve no purpose.
BYTEmark's results should be used as predictors. They can be moved to a new
platform long before native applications will be ported. The BYTEmark
benchmarks will therefore provide an early look at the potential of the
machine. Additionally, the BYTEmark permits you to "home in" on an aspect of
the overall architecture. How well does the system perform when executing
floating-point computations? Does its memory architecture help or hinder the
management of memory buffers that may fall on arbitrary address boundaries?
How does the cache work with a program whose memory access favors moving
randomly through memory as opposed to moving sequentially through memory?
The answers to these questions can give you a good idea of how well a system
would support a particular class of applications. Only a synthetic benchmark
can give the narrow view necessary to find the answers.
Dynamic Workloads
Our long history of benchmarking has taught us one thing above all others:
Tomorrow's system will go faster than today's by an amount exceeding your
wildest guess -- and then some. Dealing with this can become an unending
race.
It goes like this: You design a benchmark algorithm, you specify its
parameters (how big the array is, how many loops, etc.), you run it on
today's latest super-microcomputer, collect your data, and go home. A new
machine arrives the next day, you run your benchmark, and discover that the
test executes so quickly that the resolution of the clock routine you're
using can't keep up with it (i.e., the test is over and done before the
system clock even has a chance to tick).
If you modify your routine, the figures you collected yesterday are no good.
If you create a better clock routine by sneaking down into the system
hardware, you can kiss portability goodbye.
The BYTEmark benchmarks solve this problem by a process we'll refer to as
"dynamic workload adjustment." In principle, it simply means that if the
test runs so fast that the system clock can't time it, the benchmark
increases the test workload -- and keeps increasing it -- until enough time
is consumed to gather reliable test results.
Here's an example.
The BYTEmark benchmarks perform timing using a "stopwatch" paradigm. The
routine StartStopwatch() begins timing; StopStopwatch() ends timing and
reports the elapsed time in clock ticks. Now, "clock ticks" is a value that
varies from system to system. We'll presume that our test system provides
1000 clock ticks per second. (We'll also presume that the system actually
updates its clock 1000 times per second. Surprisingly, some systems don't do
that. One we know of will tell you that the clock provides 100 ticks per
second, but updates the clock in 5- or 6-tick increments. The resolution is
no better than somewhere around 1/18th of a second.) Here, when we say
"system" we mean not only the computer system, but the environment provided
by the C compiler. Interestingly, different C compilers for the same system
will report different clock ticks per second.
Built into the benchmarks is a global variable called GLOBALMINTICKS. This
variable is the minimum number of clock ticks that the benchmark will allow
StopStopwatch() to report.
Suppose you run the Numeric Sort benchmark. The benchmark program will
construct an array filled with random numbers, call StartStopwatch(), sort
the array, and call StopStopwatch(). If the time reported in StopStopwatch()
is less than GLOBALMINTICKS, then the benchmark will build two arrays, and
try again. If sorting two arrays took less time than GLOBALMINTICKS, the
process repeats with more arrays.
This goes on until the benchmark makes enough work so that an interval
between StartStopwatch() and StopStopwatch() exceeds GLOBALMINTICKS. Once
that happens, the test is actually run, and scores are calculated.
Notice that the benchmark didn't make bigger arrays, it made more arrays.
That's because the time taken by the sort test does not increase linearly as
the array grows, it increases by a factor of N*log(N) (where N is the size
of the array).
This principle is applied to all the benchmark tests. A machine with a less
accurate clock may be forced to sort more arrays at a time, but the results
are given in arrays per second. In this way fast machines, slow machines,
machines with accurate clocks, machines with less accurate clocks, can all
be tested with the same code.
Confidence Intervals
Another built-in feature of the BYTEmark is a set of statistical-analysis
routines. Running benchmarks is one thing; the question arises as to how
many times should a test be run until you know you have a good sampling.
Also, can you determine whether the test is stable (i.e., do results vary
widely from one execution of the benchmark to the next)?
The BYTEmark keeps score as follows: Each test (a test being a numeric
sort, a string sort, etc.) is run five times. These five scores are
averaged, the standard deviation is determined, and a 95% confidence
half-interval for the mean is calculated (using the student t
distribution). This tells us that the true average lies -- with a 95%
probability -- within plus or minus the confidence half-interval of
the calculated average. If this half-interval is within 5% of the
calculated average, the benchmarking stops. Otherwise, a new test is
run and the calculations are repeated with all of the runs done so
far, including the new one. The benchmark proceeds this way up to a
total of 30 runs. If the length of the half-interval is still bigger
than 5% of the calculated average then a warning issued that the
results might not be statistically certain before the average is
displayed.
** Fixed a statistical bug here. Uwe F. Mayer
The upshot is that, for each benchmark test, the true average is -- with a
95% level of confidence -- within 5% of the average reported. Here, the
"true average" is the average we would get were we able to run the tests
over and over again an infinite number of times.
This specification ensures that the calculation of results is controlled;
that someone running the tests in California will use the same technique for
determining benchmark results as someone running the tests in New York.
In case there is uneven system load due to other processes while this
benchmark suite executes, it might take longer to run the benchmark suite
as compared to a run an unloaded system. This is because the benchmark does
some statistical analysis to make sure that the reported results are
statistically significant (as explained above), and a high variation in
individual runs requires more runs to achieve the required statistical
confidence.
*** added last the paragraph, Uwe F. Mayer
Interpreting Results
Of course, running the benchmarks can present you with a boatload of data.
It can get mystifying, and some of the more esoteric statistical information
is valuable only to a limited audience. The big question is: What does it
all mean?
First, we should point out that the BYTEmark reports both "raw" and indexed
scores for each test. The raw score for a particular test amounts to the
"iterations per second" of that test. For example, the numeric sort test
reports as its raw score the number of arrays it was able to sort per
second.
The indexed score is the raw score of the system under test divided by the
raw score obtained on the baseline machine. As of this release, the
baseline machine is a DELL 90 Mhz Pentium XPS/90 with 16 MB of RAM and 256K
of external processor cache. (The compiler used was the Watcom C/C++ 10.0
compiler; optimizations set to "fastest possible code", 4-byte structure
alignment, Pentium code generation with Pentium register-based calling. The
operating system was MSDOS.) The indexed score serves to "normalize" the
raw scores, reducing their dynamic range and making them easier to
grasp. Simply put, if your machine has an index score of 2.0 on the numeric
sort test, it performed that test twice as fast as this 90 Mhz Pentium.
If you run all the tests (as you'll see, it is possible to perform "custom
runs", which execute only a subset of the tests) the BYTEmark will also
produce two overall index figures: Integer index and Floating-point index.
The Integer index is the geometric mean of those tests that involve only
integer processing -- numeric sort, string sort, bitfield, emulated
floating-point, assignment, Huffman, and IDEA -- while the Floating-point
index is the geometric mean of those tests that require the floating-point
coprocessor -- Fourier, neural net, and LU decomposition. You can use these
scores to get a general feel for the performance of the machine under test
as compared to the baseline 90 Mhz Pentium.
The Linux/Unix port has a second baseline machine, it is an AMD K6/233 with
32 MB RAM and 512 KB L2-cache running Linux 2.0.32 and using GNU gcc
version 2.7.2.3 and libc-5.4.38. The integer index was split as suggested
by Andrew D. Balsa <andrewbalsa@usa.net>, and reflects the realization that
memory management is important in CPU design. The original tests have been
left alone, however, the geometric mean of the tests NUMERIC SORT, FP
EMULATION, IDEA, and HUFFMAN now constitutes the integer-arithmetic focused
benchmark index, while the geometric mean of the tests STRING SORT,
BITFIELD, and ASSIGNMENT makes up the new memory index. The floating point
index has been left alone, it is still the geometric mean of FOURIER,
NEURAL NET, and LU DECOMPOSITION.
*** added the section on Linux, Uwe F. Mayer
What follows is a list of the benchmarks and associated brief remarks that
describe what the tests do: What they exercise; what a "good" result or a
"bad" result means. Keep in mind that, in this expanding universe of faster
processors, bigger caches, more elaborate memory architectures, "good" and
"bad" are indeed relative terms. A good score on today's hot new processor
will be a bad score on tomorrow's hot new processor.
These remarks are based on empirical data and profiling that we have done to
date. (NOTE: The profiling is limited to Intel and Motorola 68K on this
release. As more data is gathered, we will be refining this section.
3/14/95--RG)
Benchmark Description
Numeric sort Generic integer performance. Should
exercise non-sequential performance
of cache (or memory if cache is less
than 8K). Moves 32-bit longs at a
time, so 16-bit processors will be
at a disadvantage.
String sort Tests memory-move performance.
Should exercise non-sequential
performance of cache, with added
burden that moves are byte-wide and
can occur on odd address boundaries.
May tax the performance of
cell-based processors that must
perform additional shift operations
to deal with bytes.
Bitfield Exercises "bit twiddling"
performance. Travels through memory
in a somewhat sequential fashion;
different from sorts in that data is
merely altered in place. If
properly compiled, takes into
account 64-bit processors, which
should see a boost.
Emulated F.P. Past experience has shown this test
to be a good measurement of overall
performance.
Fourier Good measure of transcendental and
trigonometric performance of FPU.
Little array activity, so this test
should not be dependent of cache or
memory architecture.
Assignment The test moves through large integer
arrays in both row-wise and
column-wise fashion. Cache/memory
with good sequential performance
should see a boost (memory is
altered in place -- no moving as in
a sort operation). Processing is
done in 32-bit chunks -- no
advantage given to 64-bit
processors.
Huffman A combination of byte operations,
bit twiddling, and overall integer
manipulation. Should be a good
general measurement.
IDEA Moves through data sequentially in
16-bit chunks. Should provide a
good indication of raw speed.
Neural Net Small-array floating-point test
heavily dependent on the exponential
function; less dependent on overall
FPU performance. Small arrays, so
cache/memory architecture should not
come into play.
LU decomposition. A floating-point test that moves
through arrays in both row-wise and
column-wise fashion. Exercises only
fundamental math operations (+, -,
*, /).
The Command File
Purpose
The BYTEmark program allows you to override many of its default parameters
using a command file. The command file also lets you request statistical
information, as well as specify an output file to hold the test results for
later use.
You identify the command file using a command-line argument. E.G.,
C:NBENCH -cCOMFILE.DAT
tells the benchmark program to read from COMFILE.DAT in the current
directory.
The content of the command file is simply a series of parameter names and
values, each on a single line. The parameters control internal variables
that are either global in nature (i.e., they effect all tests in the
program) or are specific to a given benchmark test.
The parameters are listed in a reference guide that follows, arranged in the
following groups:
Global Parameters
Numeric Sort
String Sort
Bitfield
Emulated floating-point
Fourier coefficients
Assignment algorithm
IDEA encryption
Huffman compression
Neural net
LU decomposition
As mentioned above, those items listed under "Global Parameters" affect all
tests; the rest deal with specific benchmarks. There is no required ordering
to parameters as they appear in the command file. You can specify them in
any sequence you wish.
You should be judicious in your use of a command file. Some parameters will
override the "dynamic workload" adjustment that each test performs. Doing
this completely bypasses the benchmark code that is designed to produce an
accurate reading from your system clock. Other parameters will alter default
settings, yielding test results that cannot be compared with published
benchmark results.
A Sample Command File
Suppose you built a command file that contained the following:
ALLSTATS=T
CUSTOMRUN=T
OUTFILE=D:\DATA.DAT
DONUMSORT=T
DOLU=T
Here's what this file tells the benchmark program:
ALLSTATS=T means that you've requested a "dump" of all the statistics the
test gathers. This includes not only the standard deviations of tests run,
it also produces test-specific information such as the number of arrays
built, the array size, etc.
CUSTOMRUN=T tells the system that this is a custom run. Only tests
explicitly specified will be executed.
OUTFILE=D:\DATA.DAT will write the output of the benchmark to the file
DATA.DAT on the root of the D: drive. (If DATA.DAT already exists, output
will be appended to the file.)
DONUMSORT=T tells the system to run the numeric sort benchmark. (This was
necessary on account of the CUSTOMRUN=T line, above.)
DOLU=T tells the system to run the LU decomposition benchmark.
Command File Parameters Reference
(NOTE: Altering some global parameters can invalidate results for comparison
purposes. Those parameters are indicated in the following section by a bold
asterisk (*). If you alter any parameters so indicated, you may NOT publish
the resulting data as BYTEmark scores.)
Global Parameters
GLOBALMINTICKS=<n>
This overrides the default global_min_ticks value (defined in NBENCH1.H).
The global_min_ticks value is defined as the minimum number of clock ticks
per iteration of a particular benchmark. For example, if global_min_ticks is
set to 100 and the numeric sort benchmark is run; each iteration MUST take
at least 100 ticks, or the system will expand the work-per-iteration.
MINSECONDS=<n>
Sets the minimum number of seconds any particular test will run. This has
the effect of controlling the number of repetitions done. Default: 5.
ALLSTATS=<T|F>
Set this flag to T for a "dump" of all statistics. The information displayed
varies from test to test. Default: F.
OUTFILE=<path>
Specifies that output should go to the specified output file. Any test
results and statistical data displayed on-screen will also be written to the
file. If the file does not exist, it will be created; otherwise, new output
will be appended to an existing file. This allows you to "capture" several
runs into a single file for later review.
Note: the path should not appear in quotes. For example, something like the
following would work: OUTFILE=C:\BENCH\DUMP.DAT
CUSTOMRUN=<T|F>
Set this flag to T for a custom run. A "custom run" means that the program
will run only the benchmark tests that you explicitly specify. So, use this
flag to run a subset of the tests. Default: F.
Numeric Sort
DONUMSORT=<T|F>
Indicates whether to do the numeric sort. Default is T, unless this is a
custom run (CUSTOMRUN=T), in which case default is F.
NUMNUMARRAYS=<n>
Indicates the number of numeric arrays the system will build. Setting this
value will override the program's "dynamic workload" adjustment for this
test.*
NUMARRAYSIZE=<n>
Indicates the number of elements in each numeric array. Default is 8001
entries. (NOTE: Altering this value will invalidate the test for comparison
purposes. The performance of the numeric sort test is not related to the
array size as a linear function; i.e., an array twice as big will not take
twice as long. The relationship involves a logarithmic function.)*
NUMMINSECONDS=<n>
Overrides MINSECONDS for the numeric sort test.
String Sort
DOSTRINGSORT=<T|F>
Indicates whether to do the string sort. Default is T, unless this is a
custom run (CUSTOMRUN=T), in which case the default is F.
STRARRAYSIZE=<n>
Sets the size of the string array. Default is 8111. (NOTE: Altering this
value will invalidate the test for comparison purposes. The performance of
the string sort test is not related to the array size as a linear function;
i.e., an array twice as big will not take twice as long. The relationship
involves a logarithmic function.)*
NUMSTRARRAYS=<n>
Sets the number of string arrays that will be created to run the test.
Setting this value will override the program's "dynamic workload" adjustment
for this test.*
STRMINSECONDS=<n>
Overrides MINSECONDS for the string sort test.
Bitfield
DOBITFIELD=<T|F>
Indicates whether to do the bitfield test. Default is T, unless this is a
custom run (CUSTOMRUN=T), in which case the default is F.
NUMBITOPS=<n>
Sets the number of bitfield operations that will be performed. Setting this
value will override the program's "dynamic workload" adjustment for this
test.*
BITFIELDSIZE=<n>
Sets the number of 32-bit elements in the bitfield arrays. The default value
is dependent on the size of a long as defined by the current compiler. For a
typical compiler that defines a long to be 32 bits, the default is 32768.
(NOTE: Altering this parameter will invalidate test results for comparison
purposes.)*
BITMINSECONDS=<n>
Overrides MINSECONDS for the bitfield test.
Emulated floating-point
DOEMF=<T|F>
Indicates whether to do the emulated floating-point test. Default is T,
unless this is a custom run (CUSTOMRUN=T), in which case the default is F.
EMFARRAYSIZE=<n>
Sets the size (number of elements) of the emulated floating-point benchmark.
Default is 3000. The test builds three arrays, each of equal size. This
parameter sets the number of elements for EACH array. (NOTE: Altering this
parameter will invalidate test results for comparison purposes.)*
EMFLOOPS=<n>
Sets the number of loops per iteration of the floating-point test. Setting
this value will override the program's "dynamic workload" adjustment for
this test.*
EMFMINSECONDS=<n>
Overrides MINSECONDS for the emulated floating-point test.
Fourier coefficients
DOFOUR=<T|F>
Indicates whether to do the Fourier test. Default is T, unless this is a
custom run (CUSTOMRUN=T), in which case the default is F.
FOURASIZE=<n>
Sets the size of the array for the Fourier test. This sets the number of
coefficients the test will derive. NOTE: Specifying this value will override
the system's "dynamic workload" adjustment for this test, and may make the
results invalid for comparison purposes.*
FOURMINSECONDS=<n>
Overrides MINSECONDS for the Fourier test.
Assignment Algorithm
DOASSIGN=<T|F>
Indicates whether to do the assignment algorithm test. Default is T, unless
this is a custom run (CUSTOMRUN=T), in which case the default is F.
ASSIGNARRAYS=<n>
Indicates the number of arrays that will be built for the test. Specifying
this value will override the system's "dynamic workload" adjustment for this
test. (NOTE: The size of the arrays in the assignment algorithm is fixed at
101 x 101. Altering the array size requires adjusting global constants and
recompiling; to do so, however, would invalidate test results.)*
ASSIGNMINSECONDS=<n>
Overrides MINSECONDS for the assignment algorithm test.
IDEA encryption
DOIDEA=<T|F>
Indicates whether to do the IDEA encryption test. Default is T, unless this
is a custom run (CUSTOMRUN=T), in which case the default is F.
IDEAARRAYSIZE=<n>
Sets the size of the plain-text character array that will be encrypted by the
test. Default is 4000. The benchmark actually builds 3 arrays: 1st
plain-text, encrypted version, and 2nd plain-text. The 2nd plain-text array is
the destination for the decryption process [part of the test]. All arrays
are set to the same size. (NOTE: Specifying this value will invalidate test
results for comparison purposes.)*
IDEALOOPS=<n>
Indicates the number of loops in the IDEA test. Specifying this value will
override the system's "dynamic workload" adjustment for this test.*
IDEAMINSECONDS=<n>
Overrides MINSECONDS for the IDEA test.
Huffman compression
DOHUFF=<T|F>
Indicates whether to do the Huffman test. Default is T, unless this is a
custom run (CUSTOMRUN=T), in which case the default is F.
HUFFARRAYSIZE=<n>
Sets the size of the string buffer that will be compressed using the Huffman
test. The default is 5000. (NOTE: Altering this value will invalidate test
results for comparison purposes.)*
HUFFLOOPS=<n>
Sets the number of loops in the Huffman test. Specifying this value will
override the system's "dynamic workload" adjustment for this test.*
HUFFMINSECONDS=<n>
Overrides MINSECONDS for the Huffman test.
Neural net
DONNET=<T|F>
Indicates whether to do the Neural Net test. Default is T, unless this is a
custom run (CUSTOMRUN=T), in which case the default is F.
NNETLOOPS=<n>
Sets the number of loops in the Neural Net test. NOTE: Altering this value
overrides the benchmark's "dynamic workload" adjustment algorithm, and may
invalidate the results for comparison purposes.*
NNETMINSECONDS=<n>
Overrides MINSECONDS for the Neural Net test.
LU decomposition
DOLU=<T|F>
Indicates whether to do the LU decomposition test. Default is T, unless this
is a custom run (CUSTOMRUN=T), in which case the default is F.
LUNUMARRAYS=<n>
Sets the number of arrays in each iteration of the LU decomposition test.
Specifying this value will override the system's "dynamic workload"
adjustment for this test.*
LUMINSECONDS=<n>
Overrides MINSECONDS for the LU decomposition test.
Numeric Sort
Description
This benchmark is designed to explore how well the system sorts a numeric
array. In this case, a numeric array is a one-dimensional collection of
signed, 32-bit integers. The actual sorting is performed by a heapsort
algorithm (see the text box following for a description of the heapsort
algorithm).
It's probably unnecessary to point out (but we'll do it anyway) that sorting
is a fundamental operation in computer application software. You'll likely
find sorting routines nestled deep inside a variety of applications;
everything from database systems to operating-systems kernels.
The numeric sort benchmark reports the number of arrays it was able to sort
per second. The array size is set by a global constant (it can be overridden
by the command file -- see below).
Analysis
Optimized 486 code: Profiling of the numeric sort benchmark using Watcom's
profiler (Watcom C/C++ 10.0) indicates that the algorithm spends most of its
time in the numsift() function (specifically, about 90% of the benchmark's
time takes place in numsift()). Within numsift(), two if statements dominate
time spent:
if(array[k]<array[k+1L]) and if(array[i]<array[k])
Both statements involve indexes into arrays, so it's likely the processor is
spending a lot of time resolving the array references. (Though both
statements involve "less-than" comparisons, we doubt that much time is
consumed in performing the signed compare operation.) Though the first
statement involves array elements that are adjacent to one another, the
second does not. In fact, the second statement will probably involve
elements that are far apart from one another during early passes through the
sifting process. We expect that systems whose caching system pre-fetches
contiguous elements (often in "burst" line fills) will not have any great
advantage of systems without pre-fetch mechanisms.
Similar results were found when we profiled the numeric sort algorithm under
the Borland C/C++ compiler.
680x0 Code (Macintosh CodeWarrior): CodeWarrior's profiler is function
based; consequently, it does not allow for line-by-line analysis as does the
Watcom compiler's profiler.
However, the CodeWarrior profiler does give us enough information to note
that NumSift() only accounts for about 28% of the time consumed by the
benchmark. The outer routine, NumHeapSort() accounts for around 71% of the
time taken. It will require additional analysis to determine why the two
compilers -- Watcom and CodeWarrior divide the workload so differently. (It
may have something to do with compiler architecture, or the act of profiling
the code may produce results that are significantly different than how the
program runs under normal conditions, though that would lead one to wonder
what use profilers would be.)
Porting Considerations
The numeric sort routine should represent a trivial porting exercise. It is
not an overly large benchmark in terms of source code. Additionally, the
only external routines it calls on are for allocating and releasing memory,
and managing the stopwatch.
The numeric sort benchmark depends on the following global definitions (note
that these may be overridden by the command file):
NUMNUMARRAYS -- Sets the upper limit on the number of arrays that the
benchmark will attempt to build. The numeric sort benchmark creates work for
itself by requiring the system to sort more and more arrays...not bigger and
bigger arrays. (The latter case would skew results, because the sorting time
for heapsort is N log2 N - e.g., doubling the array size does not double the
sort time.) This constant sets the upper limit to the number of arrays the
system will build before it signals an error. The default value is 100, and
may be changed if your system exceeds this limit.
NUMARRAYSIZE - Determines the size of each array built. It has been set to
8111L and should not be tampered with. The command file entry
NUMARRAYSIZE=<n> can be used to change this value, but results produced by
doing this will make your results incompatible with other runs of the
benchmark (since results will be skewed -- see preceding paragraph).
To test for a correct execution of the numeric sort benchmark, #define the
DEBUG symbol. This will enable code that verifies that arrays are properly
sorted. You should run the benchmark program using a command file that has
only the numeric sort test enabled. If there is an error, the program will
display "SORT ERROR" (If this happens, it's possible that tons of "SORT
ERROR" messages will be emitted, so it's best not to redirect output to a
file), otherwise it will print "Numeric sort: OK" (also quite a few times).
References
Gonnet, G.H. 1984, Handbook of Algorithms and Data Structures (Reading, MA:
Addison-Wesley).
Knuth, Donald E. 1968, Fundamental Algorithms, vol 1 of The Art of Computer
Programming (Reading, MA: Addison-Wesley).
Press, William H., Flannery, Brian P., Teukolsky, Saul A., and Vetterling,
William T. 1989, Numerical Recipes in Pascal (Cambridge: Cambridge
University Press).
Heapsort
The heapsort algorithm is well-covered in a number of the popular
computer-science textbooks. In fact, it gets a pat on the back in Numerical
Recipes (Press et. al.), where the authors write:
Heapsort is our favorite sorting routine. It can be recommended
wholeheartedly for a variety of sorting applications. It is a true
"in-place" sort, requiring no auxiliary storage.
Heapsort works by building the array into a kind of a queue called a heap.
You can imagine this heap as being a form of in-memory binary tree. The
topmost (root) element of the tree is the element that -- were the array
sorted -- would be the largest element in the array. Sorting takes place by
first constructing the heap, then pulling the root off the tree, promoting
the next largest element to the root, pulling it off, and so on. (The
promotion process is known as "sifting up.")
Heapsort executes in N log2 N time even in its worst case. Unlike some other
sorting algorithms, it does not benefit from a partially sorted array
(though Gonnet does refer to a variation of heapsort, called "smoothsort,"
which does -- see references).
String Sort
Description
This benchmark is designed to gauge how well the system moves bytes around.
By that we mean, how well the system can copy a string of bytes from one
location to another; source and destination being aligned to arbitrary
addresses. (This is unlike the numeric sort array, which moves bytes
longword-at-a-time.) The strings themselves are built so as to be of random
length, ranging from no fewer than 4 bytes and no greater than 80 bytes. The
mixture of random lengths means that processors will be forced to deal with
strings that begin and end on arbitrary address boundaries.
The string sort benchmark uses the heapsort algorithm; this is the same
algorithm as is used in the numeric sort benchmark (see the sidebar on the
heapsort for a detailed description of the algorithm).
Manipulation of the strings is actually handled by two arrays. One array
holds the strings themselves; the other is a pointers array. Each member of
the pointers array carries an offset that points into the string array, so
that the ith pointer carries the offset to the ith string. This allows the
benchmark to rapidly locate the position of the ith string. (The sorting
algorithm requires exchanges of items that might be "distant" from one
another in the array. It's critical that the routine be able to rapidly find
a string based on its indexed position in the array.)
The string sort benchmark reports the number of string arrays it was able to
sort per second. The size of the array is set by a global constant.
Analysis
Optimized 486 code (Watcom C/C++ 10.0): Profiling of the string sort
benchmark indicates that it spends most of its time in the C library routine
memmove(). Within that routine, most of the execution is consumed by a pair
of instructions: rep movsw and rep movsd. These are repeated string move --
word width and repeated string move -- doubleword width, respectively.
This is precisely where we want to see the time spent. It's interesting to
note that the memmove() of the particular compiler/profiler tested (Watcom
C/C++ 10.0) was "smart" enough to do most of the moving on word or
doubleword boundaries. The string sort benchmark specifically sets arbitrary
boundaries, so we'd expect to see lots of byte-wide moves. The "smart"
memmove() is able to move bytes only when it has to, and does the remainder
of the work via words and doublewords (which can move more bits at a time).
680x0 Code (Macintosh CodeWarrior): Because CodeWarrior's profiler is
function based, it is impossible to get an idea of how much time the test
spends in library routines such as memmove(). Fortunately, as an artifact of
the early version of the benchmark, the string sort algorithm makes use of
the MoveMemory() routine in the sysspec.c file (system specific routines).
This call, on anything other than a 16-bit DOS system, calls memmove()
directly. Hence, we can get a good approximation of how much time is spent
moving bytes.
The answer is that nearly 78% of the benchmark's time is consumed by
MoveMemory(), the rest being taken up by the other routines (the
str_is_less() routine, which performs string comparisons, takes about 7% of
the time). As above, we can guess that most of the benchmark's time is
dependent on the performance of the library's memmove() routine.
Porting Considerations
As with the numeric sort routine, the string sort benchmark should be simple
to port. Simpler, in fact. The string sort benchmark routine is not
dependent on any typedef that may change from machine to machine (unless a
char type is not 8 bits).
The string sort benchmark depends on the following global definitions:
NUMSTRARRAYS - Sets the upper limit on the number of arrays that the
benchmark will attempt to build. The string sort benchmark creates work for
itself by requiring the system to sort more and more arrays, not bigger and
bigger arrays. (See section on Numeric Sort for an explanation.) This
constant sets the upper limit to the number of arrays the system will build
before it signals an error. The default value is 100, and may be changed if
your system exceeds this limit.
STRARRAYSIZE - Sets the default size of the string arrays built. We say
"arrays" because, as with the numeric sort benchmark, the system adds work
not by expanding the size of the array, but by adding more arrays. This
value is set to 8111, and should not be modified, since results would not be
comparable with other runs of the same benchmark on other machines.
To test for a correct execution of the string sort benchmark, #define
the DEBUG symbol. This will enable code that verifies the arrays are
properly sorted. Set up a command file that runs only the string sort,
and execute the benchmark program. If the routine is operating
properly, the benchmark will print "String sort: OK", this message is
printed quite often. Otherwise, the program will display "SORT ERROR"
for each pair of strings it finds out of order (which can be really
often).