2008-04-17 17:03:07 -04:00
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Copyright 2000, 2001, 2002, 2004 Free Software Foundation, Inc.
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This file is part of the GNU MP Library.
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The GNU MP Library is free software; you can redistribute it and/or modify
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it under the terms of the GNU Lesser General Public License as published by
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the Free Software Foundation; either version 2.1 of the License, or (at your
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option) any later version.
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The GNU MP Library is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
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or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
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License for more details.
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You should have received a copy of the GNU Lesser General Public License
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along with the GNU MP Library; see the file COPYING.LIB. If not, write to
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the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
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02110-1301, USA.
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GMP SPEED MEASURING AND PARAMETER TUNING
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The programs in this directory are for knowledgeable users who want to
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measure GMP routines on their machine, and perhaps tweak some settings or
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identify things that can be improved.
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The programs here are tools, not ready to run solutions. Nothing is built
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in a normal "make all", but various Makefile targets described below exist.
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Relatively few systems and CPUs have been tested, so be sure to verify that
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results are sensible before relying on them.
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MISCELLANEOUS NOTES
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--enable-assert
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Don't configure with --enable-assert, since the extra code added by
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assertion checking may influence measurements.
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Direct mapped caches
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Some effort has been made to accommodate CPUs with direct mapped caches,
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by putting data blocks more or less contiguously on the stack. But this
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will depend on TMP_ALLOC using alloca, and even then it may or may not
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be enough.
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FreeBSD 4.2 i486 getrusage
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This getrusage seems to be a bit doubtful, it looks like it's
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microsecond accurate, but sometimes ru_utime remains unchanged after a
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time of many microseconds has elapsed. It'd be good to detect this in
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the time.c initializations, but for now the suggestion is to pretend it
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doesn't exist.
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./configure ac_cv_func_getrusage=no
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NetBSD 1.4.1 m68k macintosh time base
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On this system it's been found getrusage often goes backwards, making it
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unusable (time.c getrusage_backwards_p detects this). gettimeofday
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sometimes doesn't update atomically when it crosses a 1 second boundary.
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Not sure what to do about this. Expect possible intermittent failures.
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SCO OpenUNIX 8 /etc/hw
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/etc/hw takes about a second to return the cpu frequency, which suggests
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perhaps it's measuring each time it runs. If this is annoying when
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running the speed program repeatedly then set a GMP_CPU_FREQUENCY
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environment variable (see TIME BASE section below).
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Low resolution timebase
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Parameter tuning can be very time consuming if the only timebase
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available is a 10 millisecond clock tick, to the point of being
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unusable. This is currently the case on VAX and ARM systems.
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PARAMETER TUNING
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The "tuneup" program runs some tests designed to find the best settings for
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various thresholds, like MUL_KARATSUBA_THRESHOLD. Its output can be put
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into gmp-mparam.h. The program is built and run with
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make tune
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If the thresholds indicated are grossly different from the values in the
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selected gmp-mparam.h then there may be a performance boost in applicable
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size ranges by changing gmp-mparam.h accordingly.
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Be sure to do a full reconfigure and rebuild to get any newly set thresholds
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to take effect. A partial rebuild is enough sometimes, but a fresh
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configure and make is certain to be correct.
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If a CPU has specific tuned parameters coming from a gmp-mparam.h in one of
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the mpn subdirectories then the values from "make tune" should be similar.
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But check that the configured CPU is right and there are no machine specific
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effects causing a difference.
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It's hoped the compiler and options used won't have too much effect on
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thresholds, since for most CPUs they ultimately come down to comparisons
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between assembler subroutines. Missing out on the longlong.h macros by not
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using gcc will probably have an effect.
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Some thresholds produced by the tune program are merely single values chosen
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from what's a range of sizes where two algorithms are pretty much the same
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speed. When this happens the program is likely to give somewhat different
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values on successive runs. This is noticeable on the toom3 thresholds for
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instance.
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SPEED PROGRAM
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The "speed" program can be used for measuring and comparing various
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routines, and producing tables of data or gnuplot graphs. Compile it with
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make speed
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(Or on DOS systems "make speed.exe".)
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Here are some examples of how to use it. Check the code for all the
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options.
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Draw a graph of mpn_mul_n, stepping through sizes by 10 or a factor of 1.05
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(whichever is greater).
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./speed -s 10-5000 -t 10 -f 1.05 -P foo mpn_mul_n
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gnuplot foo.gnuplot
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Compare mpn_add_n and an mpn_lshift by 1, showing times in cycles and
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showing under mpn_lshift the difference between it and mpn_add_n.
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./speed -s 1-40 -c -d mpn_add_n mpn_lshift.1
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Using option -c for times in cycles is interesting but normally only
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necessary when looking carefully at assembler subroutines. You might think
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it would always give an integer value, but this doesn't happen in practice,
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probably due to overheads in the time measurements.
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In the free-form output the "#" symbol against a measurement means the
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corresponding routine is fastest at that size. This is a convenient visual
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cue when comparing different routines. The graph data files <name>.data
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don't get this since it would upset gnuplot or other data viewers.
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TIME BASE
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The time measuring method is determined in time.c, based on what the
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configured host has available. A cycle counter is preferred, possibly
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supplemented by another method if the counter has a limited range. A
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microsecond accurate getrusage() or gettimeofday() will work quite well too.
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The cycle counters (except possibly on alpha) and gettimeofday() will depend
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on the machine being otherwise idle, or rather on other jobs not stealing
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CPU time from the measuring program. Short routines (those that complete
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within a timeslice) should work even on a busy machine.
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Some trouble is taken by speed_measure() in common.c to avoid ill effects
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from sporadic interrupts, or other intermittent things (like cron waking up
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every minute). But generally an idle machine will be necessary to be
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certain of consistent results.
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The CPU frequency is needed to convert between cycles and seconds, or for
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when a cycle counter is supplemented by getrusage() etc. The speed program
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will convert as necessary according to the output format requested. The
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tune program will work with either cycles or seconds.
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freq.c knows how to get the frequency on some systems, or can measure a
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cycle counter against gettimeofday() or getrusage(), but when that fails, or
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needs to be overridden, an environment variable GMP_CPU_FREQUENCY can be
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used (in Hertz). For example in "bash" on a 650 MHz machine,
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export GMP_CPU_FREQUENCY=650e6
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A high precision time base makes it possible to get accurate measurements in
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a shorter time.
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EXAMPLE COMPARISONS - VARIOUS
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Here are some ideas for things that can be done with the speed program.
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There's always going to be a certain amount of overhead in the time
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measurements, due to reading the time base, and in the loop that runs a
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routine enough times to get a reading of the desired precision. Noop
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functions taking various arguments are available to measure this. The
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"overhead" printed by the speed program each time in its intro is the "noop"
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routine, but note that this is just for information, it isn't deducted from
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the times printed or anything.
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./speed -s 1 noop noop_wxs noop_wxys
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To see how many cycles per limb a routine is taking, look at the time
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increase when the size increments, using option -D. This avoids fixed
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overheads in the measuring. Also, remember many of the assembler routines
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have unrolled loops, so it might be necessary to compare times at, say, 16,
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32, 48, 64 etc to see what the unrolled part is taking, as opposed to any
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finishing off.
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./speed -s 16-64 -t 16 -C -D mpn_add_n
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The -C option on its own gives cycles per limb, but is really only useful at
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big sizes where fixed overheads are small compared to the code doing the
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real work. Remember of course memory caching and/or page swapping will
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affect results at large sizes.
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./speed -s 500000 -C mpn_add_n
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Once a calculation stops fitting in the CPU data cache, it's going to start
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taking longer. Exactly where this happens depends on the cache priming in
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the measuring routines, and on what sort of "least recently used" the
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hardware does. Here's an example for a CPU with a 16kbyte L1 data cache and
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32-bit limb, showing a suddenly steeper curve for mpn_add_n at about 2000
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limbs.
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./speed -s 1-4000 -t 5 -f 1.02 -P foo mpn_add_n
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gnuplot foo.gnuplot
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When a routine has an unrolled loop for, say, multiples of 8 limbs and then
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an ordinary loop for the remainder, it can happen that it's actually faster
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to do an operation on, say, 8 limbs than it is on 7 limbs. The following
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draws a graph of mpn_sub_n, to see whether times smoothly increase with
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size.
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./speed -s 1-100 -c -P foo mpn_sub_n
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gnuplot foo.gnuplot
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If mpn_lshift and mpn_rshift have special case code for shifts by 1, it
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ought to be faster (or at least not slower) than shifting by, say, 2 bits.
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./speed -s 1-200 -c mpn_rshift.1 mpn_rshift.2
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An mpn_lshift by 1 can be done by mpn_add_n adding a number to itself, and
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if the lshift isn't faster there's an obvious improvement that's possible.
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./speed -s 1-200 -c mpn_lshift.1 mpn_add_n_self
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On some CPUs (AMD K6 for example) an "in-place" mpn_add_n where the
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destination is one of the sources is faster than a separate destination.
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Here's an example to see this. ".1" selects dst==src1 for mpn_add_n (and
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mpn_sub_n), for other values see speed.h SPEED_ROUTINE_MPN_BINARY_N_CALL.
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./speed -s 1-200 -c mpn_add_n mpn_add_n.1
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The gmp manual points out that divisions by powers of two should be done
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using a right shift because it'll be significantly faster than an actual
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division. The following shows by what factor mpn_rshift is faster than
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mpn_divrem_1, using division by 32 as an example.
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./speed -s 10-20 -r mpn_rshift.5 mpn_divrem_1.32
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EXAMPLE COMPARISONS - MULTIPLICATION
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mul_basecase takes a ".<r>" parameter which is the first (larger) size
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parameter. For example to show speeds for 20x1 up to 20x15 in cycles,
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./speed -s 1-15 -c mpn_mul_basecase.20
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mul_basecase with no parameter does an NxN multiply, so for example to show
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speeds in cycles for 1x1, 2x2, 3x3, etc, up to 20x20, in cycles,
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./speed -s 1-20 -c mpn_mul_basecase
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sqr_basecase is implemented by a "triangular" method on most CPUs, making it
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up to twice as fast as mul_basecase. In practice loop overheads and the
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products on the diagonal mean it falls short of this. Here's an example
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running the two and showing by what factor an NxN mul_basecase is slower
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than an NxN sqr_basecase. (Some versions of sqr_basecase only allow sizes
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below SQR_KARATSUBA_THRESHOLD, so if it crashes at that point don't worry.)
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./speed -s 1-20 -r mpn_sqr_basecase mpn_mul_basecase
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The technique described above with -CD for showing the time difference in
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cycles per limb between two size operations can be done on an NxN
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mul_basecase using -E to change the basis for the size increment to N*N.
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For instance a 20x20 operation is taken to be doing 400 limbs, and a 16x16
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doing 256 limbs. The following therefore shows the per crossproduct speed
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of mul_basecase and sqr_basecase at around 20x20 limbs.
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./speed -s 16-20 -t 4 -CDE mpn_mul_basecase mpn_sqr_basecase
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Of course sqr_basecase isn't really doing NxN crossproducts, but it can be
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interesting to compare it to mul_basecase as if it was. For sqr_basecase
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the -F option can be used to base the deltas on N*(N+1)/2 operations, which
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is the triangular products sqr_basecase does. For example,
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./speed -s 16-20 -t 4 -CDF mpn_sqr_basecase
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Both -E and -F are preliminary and might change. A consistent approach to
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using them when claiming certain per crossproduct or per triangularproduct
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speeds hasn't really been established, but the increment between speeds in
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the range karatsuba will call seems sensible, that being k to k/2. For
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instance, if the karatsuba threshold was 20 for the multiply and 30 for the
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square,
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./speed -s 10-20 -t 10 -CDE mpn_mul_basecase
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./speed -s 15-30 -t 15 -CDF mpn_sqr_basecase
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EXAMPLE COMPARISONS - MALLOC
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The gmp manual recommends application programs avoid excessive initializing
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and clearing of mpz_t variables (and mpq_t and mpf_t too). Every new
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variable will at a minimum go through an init, a realloc for its first
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store, and finally a clear. Quite how long that takes depends on the C
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library. The following compares an mpz_init/realloc/clear to a 10 limb
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mpz_add. Don't be surprised if the mallocing is quite slow.
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./speed -s 10 -c mpz_init_realloc_clear mpz_add
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On some systems malloc and free are much slower when dynamic linked. The
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speed-dynamic program can be used to see this. For example the following
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measures malloc/free, first static then dynamic.
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./speed -s 10 -c malloc_free
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./speed-dynamic -s 10 -c malloc_free
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Of course a real world program has big problems if it's doing so many
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mallocs and frees that it gets slowed down by a dynamic linked malloc.
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EXAMPLE COMPARISONS - STRING CONVERSIONS
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mpn_get_str does a binary to string conversion. The base is specified with
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a ".<r>" parameter, or decimal by default. Power of 2 bases are much faster
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than general bases. The following compares decimal and hex for instance.
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./speed -s 1-20 -c mpn_get_str mpn_get_str.16
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Smaller bases need more divisions to split a given size number, and so are
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slower. The following compares base 3 and base 9. On small operands 9 will
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be nearly twice as fast, though at bigger sizes this reduces since in the
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current implementation both divide repeatedly by 3^20 (or 3^40 for 64 bit
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limbs) and those divisions come to dominate.
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./speed -s 1-20 -cr mpn_get_str.3 mpn_get_str.9
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mpn_set_str does a string to binary conversion. The base is specified with
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a ".<r>" parameter, or decimal by default. Power of 2 bases are faster than
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general bases on large conversions.
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./speed -s 1-512 -f 2 -c mpn_set_str.8 mpn_set_str.10
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mpn_set_str also has some special case code for decimal which is a bit
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faster than the general case, basically by giving the compiler a chance to
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optimize some multiplications by 10.
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./speed -s 20-40 -c mpn_set_str.9 mpn_set_str.10 mpn_set_str.11
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EXAMPLE COMPARISONS - GCDs
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mpn_gcd_1 has a threshold for when to reduce using an initial x%y when both
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x and y are single limbs. This isn't tuned currently, but a value can be
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established by a measurement like
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./speed -s 10-32 mpn_gcd_1.10
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This runs src[0] from 10 to 32 bits, and y fixed at 10 bits. If the div
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threshold is high, say 31 so it's effectively disabled then a 32x10 bit gcd
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is done by nibbling away at the 32-bit operands bit-by-bit. When the
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threshold is small, say 1 bit, then an initial x%y is done to reduce it to a
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10x10 bit operation.
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The threshold in mpn/generic/gcd_1.c or the various assembler
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implementations can be tweaked up or down until there's no more speedups on
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interesting combinations of sizes. Note that this affects only a 1x1 limb
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operation and so isn't very important. (An Nx1 limb operation always does
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an initial modular reduction, using mpn_mod_1 or mpn_modexact_1_odd.)
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SPEED PROGRAM EXTENSIONS
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Potentially lots of things could be made available in the program, but it's
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been left at only the things that have actually been wanted and are likely
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to be reasonably useful in the future.
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Extensions should be fairly easy to make though. speed-ext.c is an example,
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in a style that should suit one-off tests, or new code fragments under
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development.
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many.pl is a script for generating a new speed program supplemented with
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alternate versions of the standard routines. It can be used for measuring
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experimental code, or for comparing different implementations that exist
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within a CPU family.
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THRESHOLD EXAMINING
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The speed program can be used to examine the speeds of different algorithms
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to check the tune program has done the right thing. For example to examine
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the karatsuba multiply threshold,
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./speed -s 5-40 mpn_mul_basecase mpn_kara_mul_n
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When examining the toom3 threshold, remember it depends on the karatsuba
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threshold, so the right karatsuba threshold needs to be compiled into the
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library first. The tune program uses specially recompiled versions of
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mpn/mul_n.c etc for this reason, but the speed program simply uses the
|
2009-02-12 07:25:23 -05:00
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normal libmpir.la.
|
2008-04-17 17:03:07 -04:00
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Note further that the various routines may recurse into themselves on sizes
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far enough above applicable thresholds. For example, mpn_kara_mul_n will
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recurse into itself on sizes greater than twice the compiled-in
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MUL_KARATSUBA_THRESHOLD.
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When doing the above comparison between mul_basecase and kara_mul_n what's
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probably of interest is mul_basecase versus a kara_mul_n that does one level
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of Karatsuba then calls to mul_basecase, but this only happens on sizes less
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than twice the compiled MUL_KARATSUBA_THRESHOLD. A larger value for that
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setting can be compiled-in to avoid the problem if necessary. The same
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applies to toom3 and DC, though in a trickier fashion.
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There are some upper limits on some of the thresholds, arising from arrays
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dimensioned according to a threshold (mpn_mul_n), or asm code with certain
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sized displacements (some x86 versions of sqr_basecase). So putting huge
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values for the thresholds, even just for testing, may fail.
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FUTURE
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Make a program to check the time base is working properly, for small and
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|
large measurements. Make it able to test each available method, including
|
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perhaps the apparent resolution of each.
|
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Make a general mechanism for specifying operand overlap, and a syntax like
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|
maybe "mpn_add_n.dst=src2" to select it. Some measuring routines do this
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sort of thing with the "r" parameter currently.
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----------------
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Local variables:
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mode: text
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fill-column: 76
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End:
|