Commit Graph

479 Commits

Author SHA1 Message Date
Bruce Evans
43590b1517 Optimize the 9pi/2 < |x| <= 2**19pi/2 case on amd64 and i386 by avoiding
the the double to int conversion operation which is very slow on these
arches.  Assume that the current rounding mode is the default of
round-to-nearest and use rounding operations in this mode instead of
faking this mode using the round-towards-zero mode for conversion to
int.  Round the double to an integer as a double first and as an int
second since the double result is needed much earler.

Double rounding isn't a problem since we only need a rough approximation.
We didn't support other current rounding modes and produce much larger
errors than before if called in a non-default mode.

This saves an average about 10 cycles on amd64 (A64) and about 25 on
i386 (A64) for x in the above range.  In some cases the saving is over
25%.  Most cases with |x| < 1000pi now take about 88 cycles for cos
and sin (with certain CFLAGS, etc.), except on i386 where cos and sin
(but not cosf and sinf) are much slower at 111 and 121 cycles respectivly
due to the compiler only optimizing well for float precision.  A64
hardware cos and sin are slower at 105 cycles on i386 and 110 cycles
on amd64.
2008-02-22 15:55:14 +00:00
Bruce Evans
0ddfa46b44 Add an irint() function in inline asm for amd64 and i386. irint() is
the same as lrint() except it returns int instead of long.  Though the
extern lrint() is fairly fast on these arches, it still takes about
12 cycles longer than the inline version, and 12 cycles is a lot in
applications where [li]rint() is used to avoid slow conversions that
are only a couple of times slower.

This is only for internal use.  The libm versions of *rint*() should
also be inline, but that would take would take more header engineering.
Implementing irint() instead of lrint() also avoids a conflict with
the extern declaration of the latter.
2008-02-22 14:11:03 +00:00
Bruce Evans
f839bac29c Optimize the conversion to bits a little (by about 11 cycles or 16%
on i386 (A64), 5 cycles on amd64 (A64), and 3 cycles on ia64).  gcc
tends to generate very bad code for accessing floating point values
as bits except when the integer accesses have the same width as the
floating point values, and direct accesses to bit-fields (as is common
only for long double precision) always gives such accesses.  Use the
expsign access method, which is good for 80-bit long doubles and
hopefully no worse for 128-bit long doubles.  Now the generated code
is less bad.  There is still unnecessary copying of the arg on amd64
and i386 and mysterious extra slowness on amd64.
2008-02-22 11:59:05 +00:00
Bruce Evans
a7aa8cc980 Optimize the fixup for +-0 by using better classification for this case
and by using a table lookup to avoid a branch when this case occurs.
On i386, this saves 1-4 cycles out of about 64 for non-large args.
2008-02-22 10:04:53 +00:00
Bruce Evans
33843eef65 Fix rintl() on signaling NaNs and unsupported formats. 2008-02-22 09:21:14 +00:00
David Schultz
5aa554c7e5 s/rcsid/__FBSDID/ 2008-02-22 02:30:36 +00:00
David Schultz
fab324dfa4 Remove an unused variable. 2008-02-22 02:27:34 +00:00
David Schultz
7cd50f4d94 Eliminate some warnings. 2008-02-22 02:26:51 +00:00
Bruce Evans
f21d26becb Merge cosmetic changes from e_rem_pio2.c 1.10 (convert to __FBSDID();
fix indentation and return type of __ieee754_rem_pio2()).

Remove unused variables.
2008-02-19 15:42:46 +00:00
Bruce Evans
9e9d3bc9f1 Optimize for 3pi/4 <= |x| <= 9pi/4 in much the same way as for
pi/4 <= |x| <= 3pi/4.  Use the same branch ladder as for float precision.
Remove the optimization for |x| near pi/2 and don't do it near the
multiples of pi/2 in the newly optimized range, since it requires
fairly large code to handle only relativley few cases.  Ifdef out
optimization for |x| <= pi/4 since this case can't occur because it
is done in callers.

On amd64 (A64), for cos() and sin() with uniformly distributed args,
no cache misses, some parallelism in the caller, and good but not great
CC and CFLAGS, etc., this saves about 40 cycles or 38% in the newly
optimized range, or about 27% on average across the range |x| <= 2pi
(~65 cycles for most args, while the A64 hardware fcos and fsin take
~75 cycles for half the args and 125 cycles for the other half).  The
speedup for tan() is much smaller, especially relatively.  The speedup
on i386 (A64) is slightly smaller, especially relatively.  i386 is
still much slower than amd64 here (unlike in the float case where it
is slightly faster).
2008-02-19 15:30:58 +00:00
Bruce Evans
9ce8756044 Rearrange the polynomial evaluation for better parallelism. This
saves an average of about 8 cycles or 5% on A64 (amd64 and i386 --
more in cycles but about the same percentage on i386, and more with
old versions of gcc) with good CFLAGS and some parallelism in the
caller.  As usual, it takes a couple more multiplications so it will
be slower on old machines.

Convert to __FBSDID().
2008-02-19 12:54:14 +00:00
David Schultz
345241c5e0 Document return values better. 2008-02-18 19:02:49 +00:00
David Schultz
71c11dd528 Add tgammaf() as a simple wrapper around tgamma(). 2008-02-18 17:27:11 +00:00
Bruce Evans
be396b71c1 2 long double constants were missing L suffixes. This helped break tanl()
on !(amd64 || i386).  It gave slightly worse than double precision in some
cases.  tanl() now passes tests of 2^24 values on ia64.
2008-02-18 15:39:52 +00:00
Bruce Evans
19a9e1bb1c Fix a typo which broke k_tanl.c on !(amd64 || i386). 2008-02-18 14:09:41 +00:00
Bruce Evans
38662c9698 Inline __ieee754__rem_pio2(). With gcc4-2, this gives an average
optimization of about 10% for cos(x), sin(x) and tan(x) on
|x| < 2**19*pi/2.  We didn't do this before because __ieee754__rem_pio2()
is too large and complicated for gcc-3.3 to inline very well.  We don't
do this for float precision because it interferes with optimization
of the usual (?) case (|x| < 9pi/4) which is manually inlined for float
precision only.

This has some rough edges:
- some static data is duplicated unnecessarily.  There isn't much after
  the recent move of large tables to k_rem_pio2.c, and some static data
  is duplicated to good affect (all the data static const, so that the
  compiler can evaluate expressions like 2*pio2 at compile time and
  generate even more static data for the constant for this).
- extern inline is used (for the same reason as in previous inlining of
  k_cosf.c etc.), but C99 apparently doesn't allow extern inline
  functions with static data, and gcc will eventually warn about this.

Convert to __FBSDID().

Indent __ieee754_rem_pio2()'s declaration consistently (its style was
made inconsistent with fdlibm a while ago, so complete this).

Fix __ieee754_rem_pio2()'s return type to match its prototype.  Someone
changed too many ints to int32_t's when fixing the assumption that all
ints are int32_t's.
2008-02-18 14:02:12 +00:00
David Schultz
842d1d5c98 Use volatile hacks to make sure exp() generates an underflow
exception when it's supposed to. Previously, gcc -O2 was optimizing
away the statement that generated it.
2008-02-17 21:53:19 +00:00
David Schultz
234b60cd97 Hook up sinl(), cosl(), and tanl() to the build. 2008-02-17 07:33:51 +00:00
David Schultz
8e77cc6431 Add implementations of sinl(), cosl(), and tanl().
Submitted by:	Steve Kargl <sgk@apl.washington.edu>
2008-02-17 07:33:12 +00:00
David Schultz
f869a8c5f3 Documentation for sinl(), cosl(), and tanl(). 2008-02-17 07:32:44 +00:00
David Schultz
61f955827d Add kernel functions for 128-bit long doubles. These could be improved
a bit, but access to a freebsd/sparc64 machine is needed.

Submitted by:	bde and Steve Kargl <sgk@apl.washington.edu> (earlier version)
2008-02-17 07:32:31 +00:00
David Schultz
de336b0c5e Add kernel functions for 80-bit long doubles. Many thanks to Steve and
Bruce for putting lots of effort into these; getting them right isn't
easy, and they went through many iterations.

Submitted by:	Steve Kargl <sgk@apl.washington.edu> with revisions from bde
2008-02-17 07:32:14 +00:00
David Schultz
079299f710 Add more pi for long doubles. Also, avoid storing multiple copies
of the pi/2 array, as it is unlikely to vary, except in Indiana.
2008-02-17 07:31:59 +00:00
Bruce Evans
63b4a1f80c Sigh, the weak reference for ceill(), floorl() and truncl() was in
unreachable code due to a missing include.  This kept arm and powerpc
broken.

Reported by:	sam, grehan
2008-02-15 07:01:40 +00:00
Bruce Evans
5014f8ded4 Oops, the weak reference for ceill(), floorl() and truncl() was in the
wrong file.  This broke arm and powerpc.

Reported by:	grehan
2008-02-14 15:10:34 +00:00
Bruce Evans
3365b45e5e Use the expression fabs(x+0.0)+fabs(y+0.0) instad of a+b (where a is
|x| or |y| and b is |y| or |x|) when mixing NaN arg(s).

hypot*() had its own foot shooting for mixing NaNs -- it swaps the
args so that |x| in bits is largest, but does this before quieting
signaling NaNs, so on amd64 (where the result of adding NaNs depends
on the order) it gets inconsistent results if setting the quiet bit
makes a difference, just like a similar ia64 and i387 hardware comparison.
The usual fix (see e_powf.c 1.13 for more details) of mixing using
(a+0.0)+-(b+0.0) doesn't work on amd64 if the args are swapped (since
the rder makes a difference with SSE). Fortunately, the original args
are unchanged and don't need to be swapped when we let the hardware
decide the mixing after quieting them, but we need to take their
absolute value.

hypotf() doesn't seem to have any real bugs masked by this non-bug.
On amd64, its maximum error in 2^32 trials on amd64 is now 0.8422 ulps,
and on i386 the maximum error is unchanged and about the same, except
with certain CFLAGS it magically drops to 0.5 (perfect rounding).

Convert to __FBSDID().
2008-02-14 13:44:03 +00:00
Bruce Evans
b4437c3d32 Fix the hi+lo decomposition for 2/(3ln2). The decomposition needs to
be into 12+24 bits of precision for extra-precision multiplication,
but was into 13+24 bits.  On i386 with -O1 the bug was hidden by
accidental extra precision, but on amd64, in 2^32 trials the bug
caused about 200000 errors of more than 1 ulp, with a maximum error
of about 80 ulps.  Now the maximum error in 2^32 trials on amd64
is 0.8573 ulps.  It is still 0.8316 ulps on i386 with -O1.

The nearby decomposition of 1/ln2 and the decomposition of 2/(3ln2) in
the double precision version seem to be sub-optimal but not broken.
2008-02-14 10:23:51 +00:00
Bruce Evans
011cbae1fe Use the expression (x+0.0)-(y+0.0) instead of x+y when mixing NaN arg(s).
This uses 2 tricks to improve consistency so that more serious problems
aren't hidden in simple regression tests by noise for the NaNs:

- for a signaling NaN, adding 0.0 generates the invalid exception and
  converts to a quiet NaN, and doesn't have too many effects for other
  types of args (it converts -0 to +0 in some rounding modes, but that
  hopefully doesn't change the result after adding the NaN arg).  This
  avoids some inconsistencies on i386 and ia64.  On these arches, the
  result of an operation on 2 NaNs is apparently the largest or the
  smallest of the NaNs as bits (consistently largest or smallest for
  each arch, but the opposite).  I forget which way the comparison
  goes and if the sign bit affects it.  The quiet bit is is handled
  poorly by not always setting it before the comparision or ignoring
  it.  Thus if one of the args was originally a signaling NaN and the
  other was originally a quiet NaN, then the result depends too much
  on whether the signaling NaN has been quieted at this point, which
  in turn depends on optimizations and promotions.  E.g., passing float
  signaling NaNs to double functions must quiet them on conversion;
  on i387, loading a signaling NaN of type float or double (but not
  long double) into a register involves a conversion, so it quiets
  signaling NaNs, so if the addition has 2 register operands than it
  only sees quiet NaNs, but if the addition has a memory operand then
  it sees a signaling NaN iff it is in the memory operand.

- subtraction instead of addition is used to avoid a dubious optimization
  in old versions of gcc.  For SSE operations, mixing of NaNs apparently
  always gives the target operand.  This is not as good as the i387
  and ia64 behaviour.  It doesn't mix NaNs at all, and makes addition
  not quite commutative.  Old versions of gcc sometimes rewrite x+y
  to y+x and thus give different results (in bits) for NaNs.  gcc-3.3.3
  rewrites x+y to y+x for one of pow() and powf() but not the other,
  so starting from float NaN args x and y, powf(x, y) was almost always
  different from pow(x, y).

These tricks won't give consistency of 2-arg float and double functions
with long double ones on amd64, since long double ones use the i387
which has different semantics from SSE.

Convert to __FBSDID().
2008-02-14 09:42:24 +00:00
Bruce Evans
e7c95ee5fe s_ceill.c
s_floorl.c
s_truncl.c
2008-02-13 17:38:16 +00:00
Bruce Evans
74d68da630 On arches where long double is the same as double, alias ceil(), floor()
and trunc() to the corresponding long double functions.  This is not
just an optimization for these arches.  The full long double functions
have a wrong value for `huge', and the arches without full long doubles
depended on it being wrong.
2008-02-13 16:56:52 +00:00
Bruce Evans
6597187205 Fix the C version of ceill(x) for -1 < x <= -0 in all rounding modes.
The result should be -0, but was +0.
2008-02-13 15:22:53 +00:00
Bruce Evans
f01bfe5c6d Fix exp2*(x) on signaling NaNs by returning x+x as usual.
This has the side effect of confusing gcc-4.2.1's optimizer into more
often doing the right thing.  When it does the wrong thing here, it
seems to be mainly making too many copies of x with dependency chains.
This effect is tiny on amd64, but in some cases on i386 it is enormous.
E.g., on i386 (A64) with -O1, the current version of exp2() should
take about 50 cycles, but took 83 cycles before this change and 66
cycles after this change.  exp2f() with -O1 only speeded up from 51
to 47 cycles.  (exp2f() should take about 40 cycles, on an Athlon in
either i386 or amd64 mode, and now takes 42 on amd64).  exp2l() with
-O1 slowed down from 155 cycles to 123 for some args; this is unimportant
since the i386 exp2l() is a fake; the wrong thing for it seems to
involve branch misprediction.
2008-02-13 10:44:44 +00:00
Bruce Evans
828f7b4a82 Rearrange the polynomial evaluation for better parallelism. This is
faster on all machines tested (old Celeron (P2), A64 (amd64 and i386)
and ia64) except on ia64 when compiled with -O1.  It takes 2 more
multiplications, so it will be slower on old machines.  The speedup
is about 8 cycles = 17% on A64 (amd64 and i386) with best CFLAGS
and some parallelism in the caller.

Move the evaluation of 2**k up a bit so that it doesn't compete too
much with the new polynomial evaluation.  Unlike the previous
optimization, this rearrangement cannot change the result, so compilers
and CPU schedulers can do it, but they don't do it quite right yet.
This saves a whole 1 or 2 cycles on A64.
2008-02-13 08:36:13 +00:00
Bruce Evans
02ef796d23 Use hardware remainder on amd64 since it is 5 to 10 times faster than
software remainder and is already used for remquo().
2008-02-13 06:01:48 +00:00
Bruce Evans
a2ddfa5ea7 Fix remainder() and remainderf() in round-towards-minus-infinity mode
when the result is +-0.  IEEE754 requires (in all rounding modes) that
if the result is +-0 then its sign is the same as that of the first
arg, but in round-towards-minus-infinity mode an uncorrected implementation
detail always reversed the sign.  (The detail is that x-x with x's
sign positive gives -0 in this mode only, but the algorithm assumed
that x-x always has positive sign for such x.)

remquo() and remquof() seem to need the same fix, but I cannot test them
yet.

Use long doubles when mixing NaN args.  This trick improves consistency
of results on at least amd64, so that more serious problems like the
above aren't hidden in simple regression tests by noise for the NaNs.
On amd64, hardware remainder should be used since it is about 10 times
faster than software remainder and is already used for remquo(), but
it involves using the i387 even for floats and doubles, and the i387
does NaN mixing which is better than but inconsistent with SSE NaN mixing.
Software remainder() would probably have been inconsistent with
software remainderl() for the same reason if the latter existed.

Signaling NaNs cause further inconsistencies on at least ia64 and i386.

Use __FBSDID().
2008-02-12 17:11:36 +00:00
Bruce Evans
51f86873af Use double precision for z and thus for the entire calculation of
exp2(i/TBLSIZE) * p(z) instead of only for the final multiplication
and addition.  This fixes the code to match the comment that the maximum
error is 0.5010 ulps (except on machines that evaluate float expressions
in extra precision, e.g., i386's, where the evaluation was already
in extra precision).

Fix and expand the comment about use of double precision.

The relative roundoff error from evaluating p(z) in non-extra precision
was about 16 times larger than in exp2() because the interval length
is 16 times smaller.  Its maximum was at least P1 * (1.0 ulps) *
max(|z|) ~= log(2) * 1.0 * 1/32 ~= 0.0217 ulps (1.0 ulps from the
addition in (1 + P1*z) with a cancelation error when z ~= -1/32).  The
actual final maximum was 0.5313 ulps, of which 0.0303 ulps must have
come from the additional roundoff error in p(z).  I can't explain why
the additional roundoff error was almost 3/2 times larger than the rough
estimate.
2008-02-11 05:20:02 +00:00
Bruce Evans
52453261e9 As usual, use a minimax polynomial that is specialized for float
precision.  The new polynomial has degree 4 instead of 10, and a maximum
error of 2**-30.04 ulps instead of 2**-33.15.  This doesn't affect the
final error significantly; the maximum error was and is about 0.5015
ulps on i386 -O1, and the number of cases with an error of > 0.5 ulps
is increased from 13851 to 14407.

Note that the error is only this close to 0.5 ulps due to excessive
extra precision caused by compiler bugs on i386.  The extra precision
could be obtained intentionally, and is useful for keeping the error
of the hyperbolic float functions below 1 ulp, since these functions
are implemented using expm1f.  My recent change for scaling by 2**k
had the unintentional side effect of retaining extra precision for
longer, so callers of expm1f see errors of more like 0.0015 ulps than
0.5015 ulps, and for the hyperbolic functions this reduces the maximum
error from nearly about 2 ulps to about 0.75 ulps.

This is about 10% faster on i386 (A64).  expm1* is still very slow,
but now the float version is actually significantly faster.  The
algorithm is very sophisticated but not very good except on machines
with fast division.
2008-02-09 12:53:15 +00:00
Bruce Evans
6d656800db Fix a comment about coefficients and expand a related one. 2008-02-09 10:36:07 +00:00
Bruce Evans
fbe8fb4d7b Fix truncl() when the result should be -0.0L. When the result is +-0.0L,
it must have the same sign as the arg in all rounding modes, but it was
always +0.0L.
2008-02-08 01:45:52 +00:00
Bruce Evans
aa7c7c47cf Oops, fix the fix in rev.1.10. logb() and logbf() were broken on
denormals, and logb() remained broken after 1.10 because the fix for
logbf() was incompletely translated.

Convert to __FBSDID().
2008-02-08 01:22:13 +00:00
Bruce Evans
a00672cff9 Use a better method of scaling by 2**k. Instead of adding to the
exponent bits of the reduced result, construct 2**k (hopefully in
parallel with the construction of the reduced result) and multiply by
it.  This tends to be much faster if the construction of 2**k is
actually in parallel, and might be faster even with no parallelism
since adjustment of the exponent requires a read-modify-wrtite at an
unfortunate time for pipelines.

In some cases involving exp2* on amd64 (A64), this change saves about
40 cycles or 30%.  I think it is inherently only about 12 cycles faster
in these cases and the rest of the speedup is from partly-accidentally
avoiding compiler pessimizations (the construction of 2**k is now
manually scheduled for good results, and -O2 doesn't always mess this
up).  In most cases on amd64 (A64) and i386 (A64) the speedup is about
20 cycles.  The worst case that I found is expf on ia64 where this
change is a pessimization of about 10 cycles or 5%.  The manual
scheduling for plain exp[f] is harder and not as tuned.

Details specific to expm1*:
- the saving is closer to 12 cycles than to 40 for expm1* on i386 (A64).
  For some reason it is much larger for negative args.
- also convert to __FBSDID().
2008-02-07 09:42:19 +00:00
Bruce Evans
a373e66b85 Use a better method of scaling by 2**k. Instead of adding to the
exponent bits of the reduced result, construct 2**k (hopefully in
parallel with the construction of the reduced result) and multiply by
it.  This tends to be much faster if the construction of 2**k is
actually in parallel, and might be faster even with no parallelism
since adjustment of the exponent requires a read-modify-wrtite at an
unfortunate time for pipelines.

In some cases involving exp2* on amd64 (A64), this change saves about
40 cycles or 30%.  I think it is inherently only about 12 cycles faster
in these cases and the rest of the speedup is from partly-accidentally
avoiding compiler pessimizations (the construction of 2**k is now
manually scheduled for good results, and -O2 doesn't always mess this
up).  In most cases on amd64 (A64) and i386 (A64) the speedup is about
20 cycles.  The worst case that I found is expf on ia64 where this
change is a pessimization of about 10 cycles or 5%.  The manual
scheduling for plain exp[f] is harder and not as tuned.

This change ld128/s_exp2l.c has not been tested.
2008-02-07 03:17:05 +00:00
Bruce Evans
ce56838fdc As for the float trig functions and logf, use a minimax polynomial
that is specialized for float precision.  The new polynomial has degree
5 instead of 11, and a maximum error of 2**-27.74 ulps instead
of 2**-30.64.  This doesn't affect the final error significantly; the
maximum error was and is about 0.9101 ulps on amd64 -01 and the number
of cases with an error of > 0.5 ulps is actually reduced by epsilon
despite the larger error in the polynomial.

This is about 15% faster on amd64 (A64), i386 (A64) and ia64.  The asm
version is still used instead of this on i386 since it is faster and
more accurate.
2008-02-06 06:35:21 +00:00
David Schultz
b134ea7211 Adjust the exponent before converting the result from double to
float precision. This fixes some double rounding problems for
subnormals and simplifies things a bit.
2008-01-28 01:19:07 +00:00
Bruce Evans
fc84b771b4 Fix a harmless type error in 1.9. 2008-01-25 21:09:21 +00:00
Bruce Evans
f2a1477818 Fix cutoffs. This is just a cleanup and an optimization for unusual
cases which are used mainly by regression tests.

As usual, the cutoff for tiny args was not correctly translated to
float precision.  It was 2**-54 but 2**-24 works.  It must be about
2**-precision, since the error from approximating log(1+x) by x is
about the same as |x|.  Exhaustive testing shows that 2**-24 gives
perfect rounding in round-to-nearest mode.

Similarly for the cutoff for being small, except this is not used by
so many other functions.  It was 2**-29 but 2**-15 works.  It must be
a bit smaller than sqrt(2**-precision), since the error from
approximating log(1+x) by x-x*x/2 is about the same as x*x.  Exhaustive
testing shows that 2**-15 gives a maximum error of 0.5052 ulps in
round-to-nearest-mode.  The algorithm for the general case is only good
for 0.8388 ulps, so this is sufficient (but it loses slightly on i386 --
then extra precision gives 0.5032 ulps for the general case).

While investigating this, I noticed that optimizing the usual case by
falling into a middle case involving a simple polynomial evaluation
(return x-x*x/2 instead of x here) is not such a good idea since it
gives an enormous pessimization of tinier args on machines for which
denormals are slow.  Float x*x/2 is denormal when |x| ~< 2**-64 and
x*x/2 is evaluated in float precision, so it can easily be denormal
for normal x.  This is even more interesting for general polynomial
evaluations.  Multiplying out large powers of x is normally a good
optimization since it reduces dependencies, but it creates denormals
starting with quite large x.
2008-01-21 13:46:21 +00:00
Bruce Evans
85c309021f Oops, when merging from the float version to the double versions, don't
forget to translate "float" to "double".

ucbtest didn't detect the bug, but exhaustive testing of the float
case relative to the double case eventually did.  The bug only affects
args x with |x| ~> 2**19*(pi/2) on non-i386 (i386 is broken in a
different way for large args).
2008-01-20 04:09:44 +00:00
Bruce Evans
a9b721d6b2 Remove the float version of the kernel of arg reduction for pi/2, since
it should never have existed and it has not been used for many years
(floats are reduced faster using doubles).  All relevant changes (just
the workaround for broken assignment) have been merged to the double
version.
2008-01-19 22:50:50 +00:00
Bruce Evans
5b62c3808e Do an ordinary assignment in STRICT_ASSIGN() except for floats until
there is a problem with non-floats (when i386 defaults to extra
precision).  This essentially restores yesterday's behaviour for doubles
on i386 (since generic rint() isn't used and everywhere else assumed
working assignment), but for arches that use the generic rint() it
finishes restoring some of 1995's behaviour (don't waste time doing
unnecessary store/load).
2008-01-19 22:05:14 +00:00
Bruce Evans
684217d889 Use STRICT_ASSIGN() for exp2f() and exp2() instead of a volatile
variable hack for exp2f() only.

The volatile variable had a surprisingly large cost for exp2f() -- 19
cycles or 15% on i386 in the worst case observed.  This is only partly
explained by there being several references to the variable, only one
of which benefited from it being volatile.  Arches that have working
assignment are likely to benefit even more from not having any volatile
variable.

exp2() now has a chance of working with extra precision on i386.

exp2() has even more references to the variable, so it would have been
pessimized more by simply declaring the variable as volatile.  Even
the temporary volatile variable for STRICT_ASSIGN costs 5-10% on i386,
(A64) so I will change STRICT_ASSIGN() to do an ordinary assignment
until i386 defaults to extra precision.
2008-01-19 21:37:14 +00:00