diff mbox series

improves exp() and expf() performance on Sparc.

Message ID 1504306749-46787-1-git-send-email-patrick.mcgehearty@oracle.com
State New
Headers show
Series improves exp() and expf() performance on Sparc. | expand

Commit Message

Patrick McGehearty Sept. 1, 2017, 10:59 p.m. UTC
These changes will be active for all Sparc platforms.

Two versions will be available, one for platforms that support
direct fp to int register transfer (niagara4 and later, tested
by HWCAP_SPARC_CRYPTO) and a default version for platforms that do not
have that support. Both versions share src code, with the difference
being in compile time flags.

Typical performance gains for new exp() for Sparc niagara4 and later:

exp() - 8x to 14x (depending on input value)
expf() - 16x

Using the glibc perf tests,
      old exp    new exp
max   17629        178
min     399         29
mean   5317         71

The extreme max values for the old (ieee754) exp are due to the
extreme care the old algorithm takes when the true value is very near
0.5 ulp away from an value representable in double precision. The new
algorithm does not take special measures for those cases and can give
a different result that may be off from the true value by 0.51
ulp. The frequency of such differences appears to be less than one in
200 input values based on input tests of a range of 4000+ values.

Glibc correctness tests for exp() and expf() were run. Within the
test suite 3 input values were found to cause 1 bit differences (ulp)
when "FE_TONEAREST" rounding mode is set. No differences were
seen for the tested values for the other rounding modes.
Typical example:
exp(-0x1.760cd2p+0)  (-1.46113312244415283203125)
 new code:    2.31973271630014299393707e-01   0x1.db14cd799387ap-3
 old code:    2.31973271630014271638132e-01   0x1.db14cd7993879p-3
    exp    =  2.31973271630014285508337 (high precision)
Old delta: off by 0.49 ulp
New delta: off by 0.51 ulp
This is a difference of 0.02 ulp which is well within the 1 ulp requirement
although the test function reports the difference as a failure.

For expf(), no differences in the test suite were seen in
FE_TONEAREST, FE_DOWNWARD, FE_TOWARDZERO. Two differences were
seen with FE_UPWARD. For both cases, the precise value was less
than 0.00005 less than the value reported by the new code.
The difference of the old and new was 1 ulp.
Typical example:
Failure: Test: exp_upward (-0x1p-20)
Result:
 new code:  9.999990463256e-01 0x1.ffffe0p-1
 old code:  9.999991059303e-01 0x1.ffffe2p-1
 precise    9.999990463261e-01 (high precision) (using bc -l at scale=60)
---
 sysdeps/sparc/fpu/libm_endian.h                    |   32 ++
 .../sparc/sparc32/sparcv9/fpu/multiarch/Makefile   |    5 +
 .../sparc32/sparcv9/fpu/multiarch/e_exp-generic.c  |    1 +
 .../sparc32/sparcv9/fpu/multiarch/e_exp-niagara4.c |    1 +
 .../sparc32/sparcv9/fpu/multiarch/e_expf-generic.c |    1 +
 .../sparcv9/fpu/multiarch/e_expf-niagara4.c        |    1 +
 sysdeps/sparc/sparc64/fpu/multiarch/Makefile       |    5 +
 .../sparc/sparc64/fpu/multiarch/e_exp-generic.c    |   40 ++
 .../sparc/sparc64/fpu/multiarch/e_exp-niagara4.c   |   10 +
 sysdeps/sparc/sparc64/fpu/multiarch/e_exp.h        |  383 ++++++++++++++++++
 .../sparc/sparc64/fpu/multiarch/e_expf-generic.c   |   41 ++
 .../sparc/sparc64/fpu/multiarch/e_expf-niagara4.c  |   10 +
 sysdeps/sparc/sparc64/fpu/multiarch/e_expf.h       |  405 ++++++++++++++++++++
 13 files changed, 935 insertions(+), 0 deletions(-)
 create mode 100644 sysdeps/sparc/fpu/libm_endian.h
 create mode 100644 sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-generic.c
 create mode 100644 sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-niagara4.c
 create mode 100644 sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-generic.c
 create mode 100644 sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-niagara4.c
 create mode 100644 sysdeps/sparc/sparc64/fpu/multiarch/e_exp-generic.c
 create mode 100644 sysdeps/sparc/sparc64/fpu/multiarch/e_exp-niagara4.c
 create mode 100644 sysdeps/sparc/sparc64/fpu/multiarch/e_exp.h
 create mode 100644 sysdeps/sparc/sparc64/fpu/multiarch/e_expf-generic.c
 create mode 100644 sysdeps/sparc/sparc64/fpu/multiarch/e_expf-niagara4.c
 create mode 100644 sysdeps/sparc/sparc64/fpu/multiarch/e_expf.h

Comments

Joseph Myers Sept. 1, 2017, 11:13 p.m. UTC | #1
You're defining ifuncs for exp and expf (rather than __ieee754_exp, 
__exp_finite etc. as on x86_64).  But you're not doing anything to stop 
the w_exp_compat / w_expf_compat wrappers from being built that also 
define exp and expf, so I don't see how that can work without ending up 
with multiple definitions of exp and expf; I'd expect you to need to 
override the wrappers with empty files in such a case of a function 
implementation with all the error handling integrated.

I'm also concerned that you have local matherr handling which is not 
compatible with all the cases in __kernel_standard (which are not well 
tested).  If you need to have your own integrated error handling for 
performance reasons, matherr handling should be bug-compatible with the 
existing code, for both overflow and underflow.  (Or define a new symbol 
version, make the existing exp and expf into compat symbols for SPARC and 
then your new version only needs to handle errno setting, not matherr.)
Szabolcs Nagy Sept. 4, 2017, 11:43 a.m. UTC | #2
On 01/09/17 23:59, Patrick McGehearty wrote:
> --- /dev/null
> +++ b/sysdeps/sparc/fpu/libm_endian.h

is this header useful?

> +#define	XBIASED_EXP(x)	((((int *)&x)[HIXWORD] & 0x7fffffff) >> 16)
> +#define	ISZEROL(x)	(((((int *)&x)[0] & ~XSGNMSK) | ((int *)&x)[1] | \
> +				((int *)&x)[2] | ((int *)&x)[3]) == 0)

i don't see these used and such aliasing violation
is not acceptable anyway.
Patrick McGehearty Sept. 6, 2017, 8:31 p.m. UTC | #3
On 9/4/2017 6:43 AM, Szabolcs Nagy wrote:
> On 01/09/17 23:59, Patrick McGehearty wrote:
>> --- /dev/null
>> +++ b/sysdeps/sparc/fpu/libm_endian.h
> is this header useful?
>
>> +#define	XBIASED_EXP(x)	((((int *)&x)[HIXWORD] & 0x7fffffff) >> 16)
>> +#define	ISZEROL(x)	(((((int *)&x)[0] & ~XSGNMSK) | ((int *)&x)[1] | \
>> +				((int *)&x)[2] | ((int *)&x)[3]) == 0)
> i don't see these used and such aliasing violation
> is not acceptable anyway.
>
These definitions are not used in the new exp routines.
I will remove them from my next submission as well as HIXWORD and XSGNMSK.
If later porting of other math routines suggests
they might be useful, we can discuss what to do at that time.

- patrick
Patrick McGehearty Sept. 6, 2017, 8:34 p.m. UTC | #4
On 9/1/2017 6:13 PM, Joseph Myers wrote:
> You're defining ifuncs for exp and expf (rather than __ieee754_exp,
> __exp_finite etc. as on x86_64).  But you're not doing anything to stop
> the w_exp_compat / w_expf_compat wrappers from being built that also
> define exp and expf, so I don't see how that can work without ending up
> with multiple definitions of exp and expf; I'd expect you to need to
> override the wrappers with empty files in such a case of a function
> implementation with all the error handling integrated.
The sysdeps/ieee754/dbl-64/w_exp_compat.c
declares __exp (double x)
and then adds:
hidden_def (__exp)
weak_alias (__exp, exp)

I believe the weak_alias in w_exp_compat.c is overriden by the
sparc_libm_ifunc in e_exp-generic.c.  At least, I am not seeing any
link time errors about double exp declarations and I am seeing the new
code being executed (as proved by the speed and accuracy changes).

>
> I'm also concerned that you have local matherr handling which is not
> compatible with all the cases in __kernel_standard (which are not well
> tested).  If you need to have your own integrated error handling for
> performance reasons, matherr handling should be bug-compatible with the
> existing code, for both overflow and underflow.  (Or define a new symbol
> version, make the existing exp and expf into compat symbols for SPARC and
> then your new version only needs to handle errno setting, not matherr.)
>
As for error handling, I believe the extra level of indirection on
return from exp provided by the sysdeps/ieee754/dbl-64/w_exp_compat.c
routine is an anti-performance design. Every normal return from e_exp
requires an extra level of indirection and several tests/branches that
should be bypassed unless an error is detected. The e_exp code already
checks for underflow/overflow/NAN/etc. Those unnecessary tests for the
non-exceptional cases add overhead for the most frequent uses of exp().

On the other hand, once an error occurs that triggers__set_err_exp,
extra overhead is not a significant performance issue. I will add a
call __kernel_standard in that routine when _LIB_VERSION is not _IEEE_
or _POSIX_. As you point out, that will provide more consistent error
handling behavior. I'll make that change in my next exp patch
submission.

- patrick
Joseph Myers Sept. 6, 2017, 9:01 p.m. UTC | #5
On Wed, 6 Sep 2017, Patrick McGehearty wrote:

> The sysdeps/ieee754/dbl-64/w_exp_compat.c
> declares __exp (double x)
> and then adds:
> hidden_def (__exp)
> weak_alias (__exp, exp)
> 
> I believe the weak_alias in w_exp_compat.c is overriden by the
> sparc_libm_ifunc in e_exp-generic.c.  At least, I am not seeing any
> link time errors about double exp declarations and I am seeing the new
> code being executed (as proved by the speed and accuracy changes).

Then you should avoid any object code from w_exp_compat.c being linked 
into libm.so at all, by overriding it with a dummy file, rather than just 
letting certain symbols be overridden at link time.

> As for error handling, I believe the extra level of indirection on
> return from exp provided by the sysdeps/ieee754/dbl-64/w_exp_compat.c
> routine is an anti-performance design. Every normal return from e_exp

It's fairly clearly a design optimized for consistency of error handling 
in the presence of several architecture-specific implementations of the 
main function, without needing to e.g. deal with TLS in assembly code for 
accessing errno or make multiple implementations handle matherr the same 
way.  When you avoid architecture-specific implementations (especially .S 
ones) as far as possible, integrated error handling is more practical, 
especially if you also use new symbol versions to avoid needing to deal 
with matherr.

For expf performance obviously needs to be compared with Szabolcs's 
implementation (compiled with whatever options and configured 
appropriately regarding conversions to integer etc. to be optimal for 
SPARC).  For exp, I'm inclined to say performance should be compared with 
the existing exp *with the slow paths calling __slowexp removed along with 
the associated checks for whether to use those slow paths* since those 
slow paths are completely unnecessary.
Patrick McGehearty Sept. 7, 2017, 8:42 p.m. UTC | #6
On 9/6/2017 4:01 PM, Joseph Myers wrote:
> On Wed, 6 Sep 2017, Patrick McGehearty wrote:
>
>> The sysdeps/ieee754/dbl-64/w_exp_compat.c
>> declares __exp (double x)
>> and then adds:
>> hidden_def (__exp)
>> weak_alias (__exp, exp)
>>
>> I believe the weak_alias in w_exp_compat.c is overriden by the
>> sparc_libm_ifunc in e_exp-generic.c.  At least, I am not seeing any
>> link time errors about double exp declarations and I am seeing the new
>> code being executed (as proved by the speed and accuracy changes).
> Then you should avoid any object code from w_exp_compat.c being linked
> into libm.so at all, by overriding it with a dummy file, rather than just
> letting certain symbols be overridden at link time.
>
>> As for error handling, I believe the extra level of indirection on
>> return from exp provided by the sysdeps/ieee754/dbl-64/w_exp_compat.c
>> routine is an anti-performance design. Every normal return from e_exp
> It's fairly clearly a design optimized for consistency of error handling
> in the presence of several architecture-specific implementations of the
> main function, without needing to e.g. deal with TLS in assembly code for
> accessing errno or make multiple implementations handle matherr the same
> way.  When you avoid architecture-specific implementations (especially .S
> ones) as far as possible, integrated error handling is more practical,
> especially if you also use new symbol versions to avoid needing to deal
> with matherr.
>
> For expf performance obviously needs to be compared with Szabolcs's
> implementation (compiled with whatever options and configured
> appropriately regarding conversions to integer etc. to be optimal for
> SPARC).  For exp, I'm inclined to say performance should be compared with
> the existing exp *with the slow paths calling __slowexp removed along with
> the associated checks for whether to use those slow paths* since those
> slow paths are completely unnecessary.
>
The sysdeps/ieee_754 subtree has a number of direct calls into
ieee754_exp from such places as e_sinh, e_cosh, e_gamma_r, and s_erf.
While I have not found direct calls to __exp in the ieee_754 subtree,
I see overriding w_exp_compat.c as having some risk of
unexpected behavior with the only perceived benefit to be eliminating
a modest number of bytes from libm.

For exp, when I test isolated values, the factor of improvement
between ieee754 and the new code on Sparc to be in the range of 8x to
14x. That's not considering cases which trigger slowexp().

Comparing the "make bench" benchtests/bench.out for exp():
      ieee754    new
max:  17630     174
min:    399      26
mean:  5320      67

When the differences are this large and the new max is faster than the
old min, I don't see a need in doing further performance testing.

For expf, the comparison for individual values shows an improvement
in the range of 15x. benchtests does not measure expf().
Making this change will provide a clear, immediate gain in expf()
performance.

Is the Szabolcs code in its final form?  There were some discussion
of accuracy and of possible changes to the algorithm, perhaps using
a larger table. The Sparc code uses a larger table and thus may
be more accurate for some ulp sensitive values. Or it may be a non-issue
since both algorithms are using double precision for computation.

Wilco Dijkstra compared the new Sparc code to Szabolcs code on
aarch64 and found Szabolcs code to be 10% faster on aarch64.
That advantage may or may not be reversed on Sparc, but it is
close enough to justify testing.
In addition to a performance comparison, we'd want to do an
accuracy comparison to see what differences we might be accepting.
Joseph Myers Sept. 7, 2017, 9:05 p.m. UTC | #7
On Thu, 7 Sep 2017, Patrick McGehearty wrote:

> The sysdeps/ieee_754 subtree has a number of direct calls into
> ieee754_exp from such places as e_sinh, e_cosh, e_gamma_r, and s_erf.
> While I have not found direct calls to __exp in the ieee_754 subtree,
> I see overriding w_exp_compat.c as having some risk of
> unexpected behavior with the only perceived benefit to be eliminating
> a modest number of bytes from libm.

Those direct calls don't use the wrapper and so are completely irrelevant 
to the matter of overriding it.

It is quite clear that the wrapper needs to be overridden on any 
architecture providing its own exp (as opposed to __ieee754_exp) 
implementation, just as ia64 overrides it.

> For expf, the comparison for individual values shows an improvement
> in the range of 15x. benchtests does not measure expf().

Presumably you need to test with the benchmark addition Szabolcs points to 
in his patch submission.

> Making this change will provide a clear, immediate gain in expf()
> performance.

Maintainability is also important, and it points against having lots of 
architecture-specific versions.  Thus, people interested in expf 
optimization should first be helping with the review of Szabolcs's patch 
(and the benchtests addition patch it builds on).  Once that's done, it 
can provide a basis for judging the merits of architecture-specific expf 
versions (which might well also indicate improvements to Szabolcs's code 
as an alternative to adding an architecture-specific version).

For exp, when you have a better-performing C version the question should 
first be whether it can replace the existing generic C version (possibly 
then being built multiple times on architectures where that's useful) 
rather than whether to add it as architecture-specific code.  Adding a C 
version as architecture-specific code (rather than having limited 
architecture-specific hooks in a generic version) should only be once 
there is evidence of different architectures' performance characteristics 
requiring substantially different approaches.
Patrick McGehearty Sept. 7, 2017, 11:52 p.m. UTC | #8
On 9/7/2017 4:05 PM, Joseph Myers wrote:
> On Thu, 7 Sep 2017, Patrick McGehearty wrote:
>
>> The sysdeps/ieee_754 subtree has a number of direct calls into
>> ieee754_exp from such places as e_sinh, e_cosh, e_gamma_r, and s_erf.
>> While I have not found direct calls to __exp in the ieee_754 subtree,
>> I see overriding w_exp_compat.c as having some risk of
>> unexpected behavior with the only perceived benefit to be eliminating
>> a modest number of bytes from libm.
> Those direct calls don't use the wrapper and so are completely irrelevant
> to the matter of overriding it.
>
> It is quite clear that the wrapper needs to be overridden on any
> architecture providing its own exp (as opposed to __ieee754_exp)
> implementation, just as ia64 overrides it.
>
>> For expf, the comparison for individual values shows an improvement
>> in the range of 15x. benchtests does not measure expf().
> Presumably you need to test with the benchmark addition Szabolcs points to
> in his patch submission.
>
>> Making this change will provide a clear, immediate gain in expf()
>> performance.
> Maintainability is also important, and it points against having lots of
> architecture-specific versions.  Thus, people interested in expf
> optimization should first be helping with the review of Szabolcs's patch
> (and the benchtests addition patch it builds on).  Once that's done, it
> can provide a basis for judging the merits of architecture-specific expf
> versions (which might well also indicate improvements to Szabolcs's code
> as an alternative to adding an architecture-specific version).
>
> For exp, when you have a better-performing C version the question should
> first be whether it can replace the existing generic C version (possibly
> then being built multiple times on architectures where that's useful)
> rather than whether to add it as architecture-specific code.  Adding a C
> version as architecture-specific code (rather than having limited
> architecture-specific hooks in a generic version) should only be once
> there is evidence of different architectures' performance characteristics
> requiring substantially different approaches.
>


The sysdeps/ieee_754 subtree has a number of direct calls into
ieee754_exp from such places as e_sinh, e_cosh, e_gamma_r, and s_erf.
While I have not found direct calls to __exp in the ieee_754 subtree,
I see overriding w_exp_compat.c as having some risk of
unexpected behavior with the only perceived benefit to be eliminating
a modest number of bytes from libm.

As for exp performance, when I test isolated values, the factor of
improvement between ieee754 and the new code on Sparc to be in the
range of 8x to 14x. That's not considering cases which trigger
slowexp().

Comparing the "make bench" benchtests/bench.out for exp():
      ieee754    new
max:  17630     174
min:    399      26
mean:  5320      67

When the differences are this large and the new max is faster than the
old min, I don't see a need in doing further performance testing.

Moving on to expf, the comparison for individual values shows an
improvement in the range of 15x. benchtests does not measure expf().
Making this change will provide a clear, immediate gain in expf()
performance.

The Szabolcs code appears to provide similar benefits.  There were
some discussion of accuracy and of possible changes to the algorithm,
perhaps by using a larger table. The Sparc code uses a larger table and
thus may be more accurate for some ulp sensitive values. Or it may be
a non-issue since both algorithms are using double precision for
computation.

Wilco Dijkstra compared the new Sparc code to Szabolcs code on aarch64
and found Szabolcs code to be 10% faster on aarch64.  That result is
close enough to justify testing on Sparc. In addition to a performance
comparison, we'd want to compare accuracy to see if there are notable
differences.
diff mbox series

Patch

diff --git a/sysdeps/sparc/fpu/libm_endian.h b/sysdeps/sparc/fpu/libm_endian.h
new file mode 100644
index 0000000..321f7f1
--- /dev/null
+++ b/sysdeps/sparc/fpu/libm_endian.h
@@ -0,0 +1,32 @@ 
+/*
+   Define constant and macros to support Sparc big endian behavior for libm
+   Copyright (C) 2017 Free Software Foundation, Inc.
+   This file is part of the GNU C Library.
+
+   The GNU C Library is free software; you can redistribute it and/or
+   modify it under the terms of the GNU Lesser General Public
+   License as published by the Free Software Foundation; either
+   version 2.1 of the License, or (at your option) any later version.
+
+   The GNU C Library is distributed in the hope that it will be useful,
+   but WITHOUT ANY WARRANTY; without even the implied warranty of
+   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+   Lesser General Public License for more details.
+
+   You should have received a copy of the GNU Lesser General Public
+   License along with the GNU C Library; if not, see
+   <http://www.gnu.org/licenses/>.  */
+
+#ifndef _LIBM_ENDIAN_H
+#define	_LIBM_ENDIAN_H
+
+#define	HIWORD		0
+#define	LOWORD		1
+#define	HIXWORD		0		/* index of int containing exponent */
+#define	XSGNMSK		0x80000000	/* exponent bit mask within the int */
+/* XBIASED_EXP(x) must be an int expression; so ~0x80000000 is no good */
+#define	XBIASED_EXP(x)	((((int *)&x)[HIXWORD] & 0x7fffffff) >> 16)
+#define	ISZEROL(x)	(((((int *)&x)[0] & ~XSGNMSK) | ((int *)&x)[1] | \
+				((int *)&x)[2] | ((int *)&x)[3]) == 0)
+
+#endif	/* !defined(_LIBM_ENDIAN_H) */
diff --git a/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/Makefile b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/Makefile
index 2a2d374..7976fa7 100644
--- a/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/Makefile
+++ b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/Makefile
@@ -1,4 +1,6 @@ 
 ifeq ($(subdir),math)
+libm-sysdep_routines += e_exp-niagara4 e_expf-niagara4 \
+			e_exp-generic e_expf-generic
 ifeq ($(have-as-vis3),yes)
 libm-sysdep_routines += m_copysignf-vis3 m_copysign-vis3 s_fabs-vis3 \
 			s_fabsf-vis3 s_llrintf-vis3 s_llrint-vis3 \
@@ -10,4 +12,7 @@  sysdep_routines += s_copysignf-vis3 s_copysign-vis3
 CFLAGS-s_fdimf-vis3.c += -Wa,-Av9d -mvis3
 CFLAGS-s_fdim-vis3.c += -Wa,-Av9d -mvis3
 endif
+N4_CFLAGS = -mcpu=niagara4
+CFLAGS-e_exp-niagara4.c += ${N4_CFLAGS}
+CFLAGS-e_expf-niagara4.c += ${N4_CFLAGS}
 endif
diff --git a/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-generic.c b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-generic.c
new file mode 100644
index 0000000..2b984bc
--- /dev/null
+++ b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-generic.c
@@ -0,0 +1 @@ 
+#include <sparc64/fpu/multiarch/e_exp-generic.c>
diff --git a/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-niagara4.c b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-niagara4.c
new file mode 100644
index 0000000..fc29e48
--- /dev/null
+++ b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_exp-niagara4.c
@@ -0,0 +1 @@ 
+#include <sparc64/fpu/multiarch/e_exp-niagara4.c>
diff --git a/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-generic.c b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-generic.c
new file mode 100644
index 0000000..23c9a6a
--- /dev/null
+++ b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-generic.c
@@ -0,0 +1 @@ 
+#include <sparc64/fpu/multiarch/e_expf-generic.c>
diff --git a/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-niagara4.c b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-niagara4.c
new file mode 100644
index 0000000..2cd92c2
--- /dev/null
+++ b/sysdeps/sparc/sparc32/sparcv9/fpu/multiarch/e_expf-niagara4.c
@@ -0,0 +1 @@ 
+#include <sparc64/fpu/multiarch/e_expf-niagara4.c>
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/Makefile b/sysdeps/sparc/sparc64/fpu/multiarch/Makefile
index 03a271d..76f54f7 100644
--- a/sysdeps/sparc/sparc64/fpu/multiarch/Makefile
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/Makefile
@@ -1,4 +1,6 @@ 
 ifeq ($(subdir),math)
+libm-sysdep_routines += e_exp-niagara4 e_expf-niagara4 \
+			e_exp-generic e_expf-generic
 ifeq ($(have-as-vis3),yes)
 libm-sysdep_routines += m_signbitf-vis3 m_signbit-vis3 m_finitef-vis3 \
 			m_finite-vis3 m_isinff-vis3 m_isinf-vis3 \
@@ -19,4 +21,7 @@  CFLAGS-s_floor-vis3.c += -Wa,-Av9d -mvis3
 CFLAGS-s_truncf-vis3.c += -Wa,-Av9d -mvis3
 CFLAGS-s_trunc-vis3.c += -Wa,-Av9d -mvis3
 endif
+N4_CFLAGS = -mcpu=niagara4
+CFLAGS-e_exp-niagara4.c += ${N4_CFLAGS}
+CFLAGS-e_expf-niagara4.c += ${N4_CFLAGS}
 endif
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/e_exp-generic.c b/sysdeps/sparc/sparc64/fpu/multiarch/e_exp-generic.c
new file mode 100644
index 0000000..6df28bf
--- /dev/null
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/e_exp-generic.c
@@ -0,0 +1,40 @@ 
+#include <sparc-ifunc.h>
+#include <math.h>
+#include <math-svid-compat.h>
+#include <math_private.h>
+#include <errno.h>
+
+#define EXP_SPARC __exp_sparc_generic
+
+extern double EXP_SPARC (double);
+extern double __exp_niagara4 (double);
+
+sparc_libm_ifunc (exp, hwcap & HWCAP_SPARC_CRYPTO ?
+            __exp_niagara4 : EXP_SPARC);
+
+void
+__set_err_exp (double x, double result)
+{
+  if (_LIB_VERSION != _IEEE_)
+    {
+      if (_LIB_VERSION == _POSIX_)
+	{
+	  __set_errno (ERANGE);
+	}
+      else
+	{
+	  struct exception exc;
+	  exc.arg1 = x;
+	  exc.type = DOMAIN;
+	  exc.name = (char *) "exp";
+	  exc.retval = result;
+	  if (!matherr (&exc))
+	    {
+	      __set_errno (ERANGE);
+	    }
+	}
+    }
+}
+
+
+#include <sparc64/fpu/multiarch/e_exp.h>
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/e_exp-niagara4.c b/sysdeps/sparc/sparc64/fpu/multiarch/e_exp-niagara4.c
new file mode 100644
index 0000000..ce737ba
--- /dev/null
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/e_exp-niagara4.c
@@ -0,0 +1,10 @@ 
+#include <math_private.h>
+#include <math.h>
+#include <errno.h>
+
+#define EXP_SPARC __exp_niagara4
+
+extern double EXP_SPARC (double);
+extern void __set_err_exp (double, double);
+
+#include <sparc64/fpu/multiarch/e_exp.h>
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/e_exp.h b/sysdeps/sparc/sparc64/fpu/multiarch/e_exp.h
new file mode 100644
index 0000000..2730889
--- /dev/null
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/e_exp.h
@@ -0,0 +1,383 @@ 
+/* EXP function - Compute double precision exponential
+   Copyright (C) 2017 Free Software Foundation, Inc.
+   This file is part of the GNU C Library.
+
+   The GNU C Library is free software; you can redistribute it and/or
+   modify it under the terms of the GNU Lesser General Public
+   License as published by the Free Software Foundation; either
+   version 2.1 of the License, or (at your option) any later version.
+
+   The GNU C Library is distributed in the hope that it will be useful,
+   but WITHOUT ANY WARRANTY; without even the implied warranty of
+   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+   Lesser General Public License for more details.
+
+   You should have received a copy of the GNU Lesser General Public
+   License along with the GNU C Library; if not, see
+   <http://www.gnu.org/licenses/>.  */
+
+/*
+   exp(x)
+   Hybrid algorithm of Peter Tang's Table driven method (for large
+   arguments) and an accurate table (for small arguments).
+   Written by K.C. Ng, November 1988.
+   Method (large arguments):
+	1. Argument Reduction: given the input x, find r and integer k
+	   and j such that
+	             x = (k+j/32)*(ln2) + r,  |r| <= (1/64)*ln2
+ 
+	2. exp(x) = 2^k * (2^(j/32) + 2^(j/32)*expm1(r))
+	   a. expm1(r) is approximated by a polynomial:
+	      expm1(r) ~ r + t1*r^2 + t2*r^3 + ... + t5*r^6
+	      Here t1 = 1/2 exactly.
+	   b. 2^(j/32) is represented to twice double precision
+	      as TBL[2j]+TBL[2j+1].
+ 
+   Note: If divide were fast enough, we could use another approximation
+	 in 2.a:
+	      expm1(r) ~ (2r)/(2-R), R = r - r^2*(t1 + t2*r^2)
+	      (for the same t1 and t2 as above)
+ 
+   Special cases:
+	exp(INF) is INF, exp(NaN) is NaN;
+	exp(-INF)=  0;
+	for finite argument, only exp(0)=1 is exact.
+ 
+   Accuracy:
+	According to an error analysis, the error is always less than
+	an ulp (unit in the last place).  The largest errors observed
+	are less than 0.55 ulp for normal results and less than 0.75 ulp
+	for subnormal results.
+
+   Misc. info.
+	For IEEE double
+		if x >  7.09782712893383973096e+02 then exp(x) overflow
+		if x < -7.45133219101941108420e+02 then exp(x) underflow
+ */
+
+#include "libm_endian.h"
+
+extern double EXP_SPARC (double);
+
+static const double TBL[] = {
+  1.00000000000000000000e+00, 0.00000000000000000000e+00,
+  1.02189714865411662714e+00, 5.10922502897344389359e-17,
+  1.04427378242741375480e+00, 8.55188970553796365958e-17,
+  1.06714040067682369717e+00, -7.89985396684158212226e-17,
+  1.09050773266525768967e+00, -3.04678207981247114697e-17,
+  1.11438674259589243221e+00, 1.04102784568455709549e-16,
+  1.13878863475669156458e+00, 8.91281267602540777782e-17,
+  1.16372485877757747552e+00, 3.82920483692409349872e-17,
+  1.18920711500272102690e+00, 3.98201523146564611098e-17,
+  1.21524735998046895524e+00, -7.71263069268148813091e-17,
+  1.24185781207348400201e+00, 4.65802759183693679123e-17,
+  1.26905095719173321989e+00, 2.66793213134218609523e-18,
+  1.29683955465100964055e+00, 2.53825027948883149593e-17,
+  1.32523664315974132322e+00, -2.85873121003886075697e-17,
+  1.35425554693689265129e+00, 7.70094837980298946162e-17,
+  1.38390988196383202258e+00, -6.77051165879478628716e-17,
+  1.41421356237309514547e+00, -9.66729331345291345105e-17,
+  1.44518080697704665027e+00, -3.02375813499398731940e-17,
+  1.47682614593949934623e+00, -3.48399455689279579579e-17,
+  1.50916442759342284141e+00, -1.01645532775429503911e-16,
+  1.54221082540794074411e+00, 7.94983480969762085616e-17,
+  1.57598084510788649659e+00, -1.01369164712783039808e-17,
+  1.61049033194925428347e+00, 2.47071925697978878522e-17,
+  1.64575547815396494578e+00, -1.01256799136747726038e-16,
+  1.68179283050742900407e+00, 8.19901002058149652013e-17,
+  1.71861929812247793414e+00, -1.85138041826311098821e-17,
+  1.75625216037329945351e+00, 2.96014069544887330703e-17,
+  1.79470907500310716820e+00, 1.82274584279120867698e-17,
+  1.83400808640934243066e+00, 3.28310722424562658722e-17,
+  1.87416763411029996256e+00, -6.12276341300414256164e-17,
+  1.91520656139714740007e+00, -1.06199460561959626376e-16,
+  1.95714412417540017941e+00, 8.96076779103666776760e-17,
+};
+
+/*
+   For i = 0, ..., 66,
+     TBL2[2*i] is a double precision number near (i+1)*2^-6, and
+     TBL2[2*i+1] = exp(TBL2[2*i]) to within a relative error less
+     than 2^-60.
+
+   For i = 67, ..., 133,
+     TBL2[2*i] is a double precision number near -(i+1)*2^-6, and
+     TBL2[2*i+1] = exp(TBL2[2*i]) to within a relative error less
+     than 2^-60.
+*/
+static const double TBL2[] = {
+  1.56249999999984491572e-02, 1.01574770858668417262e+00,
+  3.12499999999998716305e-02, 1.03174340749910253834e+00,
+  4.68750000000011102230e-02, 1.04799100201663386578e+00,
+  6.24999999999990632493e-02, 1.06449445891785843266e+00,
+  7.81249999999999444888e-02, 1.08125780744903954300e+00,
+  9.37500000000013322676e-02, 1.09828514030782731226e+00,
+  1.09375000000001346145e-01, 1.11558061464248226002e+00,
+  1.24999999999999417133e-01, 1.13314845306682565607e+00,
+  1.40624999999995337063e-01, 1.15099294469117108264e+00,
+  1.56249999999996141975e-01, 1.16911844616949989195e+00,
+  1.71874999999992894573e-01, 1.18752938276309216725e+00,
+  1.87500000000000888178e-01, 1.20623024942098178158e+00,
+  2.03124999999361649516e-01, 1.22522561187652545556e+00,
+  2.18750000000000416334e-01, 1.24452010776609567344e+00,
+  2.34375000000003524958e-01, 1.26411844775347081971e+00,
+  2.50000000000006328271e-01, 1.28402541668774961003e+00,
+  2.65624999999982791543e-01, 1.30424587476761533189e+00,
+  2.81249999999993727240e-01, 1.32478475872885725906e+00,
+  2.96875000000003275158e-01, 1.34564708304941493822e+00,
+  3.12500000000002886580e-01, 1.36683794117380030819e+00,
+  3.28124999999993394173e-01, 1.38836250675661765364e+00,
+  3.43749999999998612221e-01, 1.41022603492570874906e+00,
+  3.59374999999992450483e-01, 1.43243386356506730017e+00,
+  3.74999999999991395772e-01, 1.45499141461818881638e+00,
+  3.90624999999997613020e-01, 1.47790419541173490003e+00,
+  4.06249999999991895372e-01, 1.50117780000011058483e+00,
+  4.21874999999996613820e-01, 1.52481791053132154090e+00,
+  4.37500000000004607426e-01, 1.54883029863414023453e+00,
+  4.53125000000004274359e-01, 1.57322082682725961078e+00,
+  4.68750000000008326673e-01, 1.59799544995064657371e+00,
+  4.84374999999985456078e-01, 1.62316021661928200359e+00,
+  4.99999999999997335465e-01, 1.64872127070012375327e+00,
+  5.15625000000000222045e-01, 1.67468485281178436352e+00,
+  5.31250000000003441691e-01, 1.70105730184840653330e+00,
+  5.46874999999999111822e-01, 1.72784505652716169344e+00,
+  5.62499999999999333866e-01, 1.75505465696029738787e+00,
+  5.78124999999993338662e-01, 1.78269274625180318417e+00,
+  5.93749999999999666933e-01, 1.81076607211938656050e+00,
+  6.09375000000003441691e-01, 1.83928148854178719063e+00,
+  6.24999999999995559108e-01, 1.86824595743221411048e+00,
+  6.40625000000009103829e-01, 1.89766655033813602671e+00,
+  6.56249999999993782751e-01, 1.92755045016753268072e+00,
+  6.71875000000002109424e-01, 1.95790495294292221651e+00,
+  6.87499999999992450483e-01, 1.98873746958227681780e+00,
+  7.03125000000004996004e-01, 2.02005552770870666635e+00,
+  7.18750000000007105427e-01, 2.05186677348799140219e+00,
+  7.34375000000008770762e-01, 2.08417897349558689513e+00,
+  7.49999999999983901766e-01, 2.11700001661264058939e+00,
+  7.65624999999997002398e-01, 2.15033791595229351046e+00,
+  7.81250000000005884182e-01, 2.18420081081563077774e+00,
+  7.96874999999991451283e-01, 2.21859696867912603579e+00,
+  8.12500000000000000000e-01, 2.25353478721320854561e+00,
+  8.28125000000008215650e-01, 2.28902279633221983346e+00,
+  8.43749999999997890576e-01, 2.32506966027711614586e+00,
+  8.59374999999999444888e-01, 2.36168417973090827289e+00,
+  8.75000000000003219647e-01, 2.39887529396710563745e+00,
+  8.90625000000013433699e-01, 2.43665208303232461162e+00,
+  9.06249999999980571097e-01, 2.47502376996297712708e+00,
+  9.21874999999984456878e-01, 2.51399972303748420188e+00,
+  9.37500000000001887379e-01, 2.55358945806293169412e+00,
+  9.53125000000003330669e-01, 2.59380264069854327147e+00,
+  9.68749999999989119814e-01, 2.63464908881560244680e+00,
+  9.84374999999997890576e-01, 2.67613877489447116176e+00,
+  1.00000000000001154632e+00, 2.71828182845907662113e+00,
+  1.01562499999999333866e+00, 2.76108853855008318234e+00,
+  1.03124999999995980993e+00, 2.80456935623711389738e+00,
+  1.04687499999999933387e+00, 2.84873489717039740654e+00,
+  -1.56249999999999514277e-02, 9.84496437005408453480e-01,
+  -3.12499999999955972718e-02, 9.69233234476348348707e-01,
+  -4.68749999999993824384e-02, 9.54206665969188905230e-01,
+  -6.24999999999976130205e-02, 9.39413062813478028090e-01,
+  -7.81249999999989314103e-02, 9.24848813216205822840e-01,
+  -9.37499999999995975442e-02, 9.10510361380034494161e-01,
+  -1.09374999999998584466e-01, 8.96394206635151680196e-01,
+  -1.24999999999998556710e-01, 8.82496902584596676355e-01,
+  -1.40624999999999361622e-01, 8.68815056262843721235e-01,
+  -1.56249999999999111822e-01, 8.55345327307423297647e-01,
+  -1.71874999999924144012e-01, 8.42084427143446223596e-01,
+  -1.87499999999996752598e-01, 8.29029118180403035154e-01,
+  -2.03124999999988037347e-01, 8.16176213022349550386e-01,
+  -2.18749999999995947686e-01, 8.03522573689063990265e-01,
+  -2.34374999999996419531e-01, 7.91065110850298847112e-01,
+  -2.49999999999996280753e-01, 7.78800783071407765057e-01,
+  -2.65624999999999888978e-01, 7.66726596070820165529e-01,
+  -2.81249999999989397370e-01, 7.54839601989015340777e-01,
+  -2.96874999999996114219e-01, 7.43136898668761203268e-01,
+  -3.12499999999999555911e-01, 7.31615628946642115871e-01,
+  -3.28124999999993782751e-01, 7.20272979955444259126e-01,
+  -3.43749999999997946087e-01, 7.09106182437399867879e-01,
+  -3.59374999999994337863e-01, 6.98112510068129799023e-01,
+  -3.74999999999994615418e-01, 6.87289278790975899369e-01,
+  -3.90624999999999000799e-01, 6.76633846161729612945e-01,
+  -4.06249999999947264406e-01, 6.66143610703522903727e-01,
+  -4.21874999999988453681e-01, 6.55816011271509125002e-01,
+  -4.37499999999999111822e-01, 6.45648526427892610613e-01,
+  -4.53124999999999278355e-01, 6.35638673826052436056e-01,
+  -4.68749999999999278355e-01, 6.25784009604591573428e-01,
+  -4.84374999999992894573e-01, 6.16082127790682609891e-01,
+  -4.99999999999998168132e-01, 6.06530659712634534486e-01,
+  -5.15625000000000000000e-01, 5.97127273421627413619e-01,
+  -5.31249999999989785948e-01, 5.87869673122352498496e-01,
+  -5.46874999999972688514e-01, 5.78755598612500032907e-01,
+  -5.62500000000000000000e-01, 5.69782824730923009859e-01,
+  -5.78124999999992339461e-01, 5.60949160814475100700e-01,
+  -5.93749999999948707696e-01, 5.52252450163048691500e-01,
+  -6.09374999999552580121e-01, 5.43690569513243682209e-01,
+  -6.24999999999984789945e-01, 5.35261428518998383375e-01,
+  -6.40624999999983457677e-01, 5.26962969243379708573e-01,
+  -6.56249999999998334665e-01, 5.18793165653890220312e-01,
+  -6.71874999999943378626e-01, 5.10750023129039609771e-01,
+  -6.87499999999997002398e-01, 5.02831577970942467104e-01,
+  -7.03124999999991118216e-01, 4.95035896926202978463e-01,
+  -7.18749999999991340260e-01, 4.87361076713623331269e-01,
+  -7.34374999999985678123e-01, 4.79805243559684402310e-01,
+  -7.49999999999997335465e-01, 4.72366552741015965911e-01,
+  -7.65624999999993782751e-01, 4.65043188134059204408e-01,
+  -7.81249999999863220523e-01, 4.57833361771676883301e-01,
+  -7.96874999999998112621e-01, 4.50735313406363247157e-01,
+  -8.12499999999990119015e-01, 4.43747310081084256339e-01,
+  -8.28124999999996003197e-01, 4.36867645705559026759e-01,
+  -8.43749999999988120614e-01, 4.30094640640067360504e-01,
+  -8.59374999999994115818e-01, 4.23426641285265303871e-01,
+  -8.74999999999977129406e-01, 4.16862019678517936594e-01,
+  -8.90624999999983346655e-01, 4.10399173096376801428e-01,
+  -9.06249999999991784350e-01, 4.04036523663345414903e-01,
+  -9.21874999999994004796e-01, 3.97772517966614058693e-01,
+  -9.37499999999994337863e-01, 3.91605626676801210628e-01,
+  -9.53124999999999444888e-01, 3.85534344174578935682e-01,
+  -9.68749999999986677324e-01, 3.79557188183094640355e-01,
+  -9.84374999999992339461e-01, 3.73672699406045860648e-01,
+  -9.99999999999995892175e-01, 3.67879441171443832825e-01,
+  -1.01562499999994315658e+00, 3.62175999080846300338e-01,
+  -1.03124999999991096011e+00, 3.56560980663978732697e-01,
+  -1.04687499999999067413e+00, 3.51033015038813400732e-01,
+};
+
+static const double 
+  half		=0.5,
+/* Following three values used to scale x to primary range */
+  invln2_32	=4.61662413084468283841e+01,	/* 0x40471547, 0x652b82fe */
+  ln2_32hi	=2.16608493865351192653e-02,	/* 0x3f962e42, 0xfee00000 */
+  ln2_32lo	=5.96317165397058656257e-12,	/* 0x3d9a39ef, 0x35793c76 */
+/* t2-t5 terms used for polynomial computation */
+  t2		=1.6666666666526086527e-1,	/* 3fc5555555548f7c */
+  t3		=4.1666666666226079285e-2,	/* 3fa5555555545d4e */
+  t4		=8.3333679843421958056e-3,	/* 3f811115b7aa905e */
+  t5		=1.3888949086377719040e-3,	/* 3f56c1728d739765 */
+  one		=1.0,
+  zero		=0.0,
+/* maximum value for x to not overflow */
+  threshold1	=7.09782712893383973096e+02,	/* 0x40862E42, 0xFEFA39EF */
+/* maximum value for -x to not underflow */
+  threshold2	=7.45133219101941108420e+02,	/* 0x40874910, 0xD52D3051 */
+/* scaling factor used when result near zero*/
+  twom54	=5.55111512312578270212e-17,	/* 0x3c900000, 0x00000000 */
+/* value used to force inexact condition */
+  small		=1.0e-100,
+/* value used to force underflow condition */
+  tiny		=1.0e-300,
+/* value used to force overflow condition*/
+  hhuge		=1.0e300;
+
+
+
+double
+EXP_SPARC (double x_arg)
+{
+  double z, t;
+  double retval;
+  int hx, ix, k, j, m;
+  union
+  {
+    int i_part[2];
+    double x;
+  } xx;
+  union
+  {
+    int y_part[2];
+    double y;
+  } yy;
+  xx.x = x_arg;
+
+  ix = xx.i_part[HIWORD];
+  hx = ix & ~0x80000000;
+
+  if (hx < 0x3ff0a2b2)
+    {				/* |x| < 3/2 ln 2 */
+      if (hx < 0x3f862e42)
+	{			/* |x| < 1/64 ln 2 */
+	  if (hx < 0x3ed00000)
+	    {			/* |x| < 2^-18 */
+	      /* raise inexact if x != 0 */
+	      if (hx < 0x3e300000)
+		{
+		  retval = one + xx.x;
+		  return (retval);
+		}
+	      retval = one + xx.x * (one + half * xx.x);
+	      return (retval);
+	    }
+	  t = xx.x * xx.x;
+	  yy.y = xx.x + (t * (half + xx.x * t2) +
+			 (t * t) * (t3 + xx.x * t4 + t * t5));
+	  retval = one + yy.y;
+	  return (retval);
+	}
+
+      /* find the multiple of 2^-6 nearest x */
+      k = hx >> 20;
+      j = (0x00100000 | (hx & 0x000fffff)) >> (0x40c - k);
+      j = (j - 1) & ~1;
+      if (ix < 0)
+	j += 134;
+      z = xx.x - TBL2[j];
+      t = z * z;
+      /* the "small" term below guarantees inexact will be raised */
+      yy.y = z + (t * (half + (z * t2 + small)) +
+		  (t * t) * (t3 + z * t4 + t * t5));
+      retval = TBL2[j + 1] + TBL2[j + 1] * yy.y;
+      return (retval);
+    }
+
+  if (hx >= 0x40862e42)
+    {				/* x is large, infinite, or nan */
+      if (hx >= 0x7ff00000)
+	{
+	  if (ix == 0xfff00000 && xx.i_part[LOWORD] == 0)
+	    return (zero);	/* exp(-inf) = 0 */
+	  return (xx.x * xx.x);	/* exp(nan/inf) is nan or inf */
+	}
+      if (xx.x > threshold1)
+	{			/* set overflow error condition */
+	  retval = hhuge * hhuge;
+	  __set_err_exp (xx.x, retval);
+	  return retval;
+	}
+      if (-xx.x > threshold2)
+	{			/* set underflow error condition */
+	  double force_underflow = tiny * tiny;
+	  math_force_eval (force_underflow);
+	  retval = zero;
+	  __set_err_exp (xx.x, retval);
+	  return retval;
+	}
+    }
+
+  t = invln2_32 * xx.x;
+  if (ix < 0)
+    t -= half;
+  else
+    t += half;
+  k = (int) t;
+  j = (k & 0x1f) << 1;
+  m = k >> 5;
+  z = (xx.x - k * ln2_32hi) - k * ln2_32lo;
+
+  /* z is now in primary range */
+  t = z * z;
+  yy.y = z + (t * (half + z * t2) + (t * t) * (t3 + z * t4 + t * t5));
+  yy.y = TBL[j] + (TBL[j + 1] + TBL[j] * yy.y);
+  if (m < -1021)
+    {
+      yy.y_part[HIWORD] += (m + 54) << 20;
+      retval = twom54 * yy.y;
+      if (retval < DBL_MIN)
+	{
+	  double force_underflow = tiny * tiny;
+	  math_force_eval (force_underflow);
+	  __set_err_exp (xx.x, retval);
+	}
+      return (retval);
+    }
+  yy.y_part[HIWORD] += m << 20;
+  return (yy.y);
+}
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/e_expf-generic.c b/sysdeps/sparc/sparc64/fpu/multiarch/e_expf-generic.c
new file mode 100644
index 0000000..cd2f26f
--- /dev/null
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/e_expf-generic.c
@@ -0,0 +1,41 @@ 
+#include <sparc-ifunc.h>
+#include <math.h>
+#include <math-svid-compat.h>
+#include <math_private.h>
+#include <errno.h>
+
+#define EXPF_SPARC __expf_sparc_generic
+
+extern float EXPF_SPARC (float);
+extern float __expf_niagara4 (float);
+extern unsigned long int hwcap;
+
+sparc_libm_ifunc (expf, hwcap & HWCAP_SPARC_CRYPTO ?
+	    __expf_niagara4 : EXPF_SPARC);
+
+void
+__set_err_expf (float x, float result)
+{
+  if (_LIB_VERSION != _IEEE_)
+    {
+      if (_LIB_VERSION == _POSIX_)
+	{
+	  __set_errno (ERANGE);
+	}
+      else
+	{
+	  struct exception exc;
+	  exc.arg1 = x;
+	  exc.type = DOMAIN;
+	  exc.name = (char *) "exp";
+	  exc.retval = result;
+	  if (!matherr (&exc))
+	    {
+	      __set_errno (ERANGE);
+	    }
+	}
+    }
+}
+
+
+#include <sparc64/fpu/multiarch/e_expf.h>
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/e_expf-niagara4.c b/sysdeps/sparc/sparc64/fpu/multiarch/e_expf-niagara4.c
new file mode 100644
index 0000000..2e20f1f
--- /dev/null
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/e_expf-niagara4.c
@@ -0,0 +1,10 @@ 
+#include <math_private.h>
+#include <math.h>
+#include <errno.h>
+
+#define EXPF_SPARC __expf_niagara4
+
+extern float EXPF_SPARC (float);
+extern void __set_err_expf (float, float);
+
+#include <sparc64/fpu/multiarch/e_expf.h>
diff --git a/sysdeps/sparc/sparc64/fpu/multiarch/e_expf.h b/sysdeps/sparc/sparc64/fpu/multiarch/e_expf.h
new file mode 100644
index 0000000..9710a08
--- /dev/null
+++ b/sysdeps/sparc/sparc64/fpu/multiarch/e_expf.h
@@ -0,0 +1,405 @@ 
+/* EXPF function - compute single precison exponential
+   Copyright (C) 2017 Free Software Foundation, Inc.
+   This file is part of the GNU C Library.
+
+   The GNU C Library is free software; you can redistribute it and/or
+   modify it under the terms of the GNU Lesser General Public
+   License as published by the Free Software Foundation; either
+   version 2.1 of the License, or (at your option) any later version.
+
+   The GNU C Library is distributed in the hope that it will be useful,
+   but WITHOUT ANY WARRANTY; without even the implied warranty of
+   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
+   Lesser General Public License for more details.
+
+   You should have received a copy of the GNU Lesser General Public
+   License along with the GNU C Library; if not, see
+   <http://www.gnu.org/licenses/>.  */
+
+
+/* INDENT OFF */
+/*
+   float expf(float x);
+   Code by K.C. Ng for SUN 5.0 libmopt
+   11/5/99
+   Method :
+	1. For |x| >= 2^7, either underflow/overflow.
+	   More precisely:
+		x > 88.722839355...(0x42B17218) => overflow;
+		x < -103.97207642..(0xc2CFF1B4) => underflow.
+	2. For |x| <  2^-6, use polynomail
+		exp(x) = 1 + x + p1*x^2 + p2*x^3
+	3. Otherwise, write |x|=(1+r)*2^n, where 0<=r<1.
+	   Let t = 2^n * (1+r) .... x > 0;
+	       t = 2^n * (1-r) .... x < 0. (x= -2**(n+1)+t)
+	   Since -6 <= n <= 6, we may break t into
+	   six 6-bits chunks:
+                      -5     -11     -17     -23     -29
+           t=j *2+j *2  +j *2   +j *2   +j *2   +j *2
+              1    2      3       4       5       6
+
+	   where 0 <= j  < 64 for i = 1,...,6.
+		       i
+	   Note that since t has only 24 significant bits,
+	   either j  or j  must be 0.
+		   1     6
+					       7-6i
+	   One may define j  by   (int) ( t * 2     ) mod 64
+			   i
+	   mathematically. In actual implementation, they can
+	   be obtained by manipulating the exponent and
+	   mantissa bits as follow:
+		Let ix = (HEX(x)&0x007fffff)|0x00800000.
+		If n>=0, let ix=ix<<n, then j =0 and
+					     6
+		    j  = ix>>(30-6i)) mod 64  ...i=1,...,5
+		     i
+		Otherwise, let ix=ix<<(j+6), then j = 0 and
+						   1
+		    j  = ix>>(36-6i)) mod 64  ...i=2,...,6
+		     i
+
+	4. Compute exp(t) by table look-up method.
+	   Precompute ET[k] = exp(j*2^(7-6i)), k=j+64*(6-i).
+	   Then
+	   exp(t) = ET[j +320]*ET[j +256]*ET[j +192]*
+		        1          2          3
+
+		    ET[j +128]*ET[j +64]*ET[j ]
+			4          5         6
+
+				  n+1
+	5. If x < 0, return exp(-2   )* exp(t). Note that
+	   -6 <= n <= 6. Let k = n - 6, then we can
+	   precompute
+	                 k-5          n+1
+           EN[k] = exp(-2   ) = exp(-2   ) for k=0,1,...,12.
+
+
+   Special cases:
+	exp(INF) is INF, exp(NaN) is NaN;
+	exp(-INF) = 0;
+	for finite argument, only exp(0) = 1 is exact.
+
+   Accuracy:
+	All calculations are done in double precision except for
+	the case |x| < 2^-6.  When |x| < 2^-6, the error is less
+	than 0.55 ulp.  When |x| >= 2^-6, the error is less than
+	0.51 ulp.
+ */
+/* INDENT ON */
+
+#include "libm_endian.h"
+
+extern float EXP_SPARC (float);
+
+
+/*
+ * ET[k] = exp(j*2^(7-6i)) , where j = k mod 64, i = k/64
+ */
+static const double ET[] = {
+  1.00000000000000000000e+00, 1.00000000186264514923e+00,
+  1.00000000372529029846e+00, 1.00000000558793544769e+00,
+  1.00000000745058059692e+00, 1.00000000931322574615e+00,
+  1.00000001117587089539e+00, 1.00000001303851604462e+00,
+  1.00000001490116119385e+00, 1.00000001676380656512e+00,
+  1.00000001862645171435e+00, 1.00000002048909686359e+00,
+  1.00000002235174201282e+00, 1.00000002421438716205e+00,
+  1.00000002607703253332e+00, 1.00000002793967768255e+00,
+  1.00000002980232283178e+00, 1.00000003166496798102e+00,
+  1.00000003352761335229e+00, 1.00000003539025850152e+00,
+  1.00000003725290365075e+00, 1.00000003911554879998e+00,
+  1.00000004097819417126e+00, 1.00000004284083932049e+00,
+  1.00000004470348446972e+00, 1.00000004656612984100e+00,
+  1.00000004842877499023e+00, 1.00000005029142036150e+00,
+  1.00000005215406551073e+00, 1.00000005401671088201e+00,
+  1.00000005587935603124e+00, 1.00000005774200140252e+00,
+  1.00000005960464655175e+00, 1.00000006146729192302e+00,
+  1.00000006332993707225e+00, 1.00000006519258244353e+00,
+  1.00000006705522759276e+00, 1.00000006891787296404e+00,
+  1.00000007078051811327e+00, 1.00000007264316348454e+00,
+  1.00000007450580863377e+00, 1.00000007636845400505e+00,
+  1.00000007823109937632e+00, 1.00000008009374452556e+00,
+  1.00000008195638989683e+00, 1.00000008381903526811e+00,
+  1.00000008568168063938e+00, 1.00000008754432578861e+00,
+  1.00000008940697115989e+00, 1.00000009126961653116e+00,
+  1.00000009313226190244e+00, 1.00000009499490705167e+00,
+  1.00000009685755242295e+00, 1.00000009872019779422e+00,
+  1.00000010058284316550e+00, 1.00000010244548853677e+00,
+  1.00000010430813368600e+00, 1.00000010617077905728e+00,
+  1.00000010803342442856e+00, 1.00000010989606979983e+00,
+  1.00000011175871517111e+00, 1.00000011362136054238e+00,
+  1.00000011548400591366e+00, 1.00000011734665128493e+00,
+  1.00000000000000000000e+00, 1.00000011920929665621e+00,
+  1.00000023841860752327e+00, 1.00000035762793260119e+00,
+  1.00000047683727188996e+00, 1.00000059604662538959e+00,
+  1.00000071525599310007e+00, 1.00000083446537502141e+00,
+  1.00000095367477115360e+00, 1.00000107288418149665e+00,
+  1.00000119209360605055e+00, 1.00000131130304481530e+00,
+  1.00000143051249779091e+00, 1.00000154972196497738e+00,
+  1.00000166893144637470e+00, 1.00000178814094198287e+00,
+  1.00000190735045180190e+00, 1.00000202655997583179e+00,
+  1.00000214576951407253e+00, 1.00000226497906652412e+00,
+  1.00000238418863318657e+00, 1.00000250339821405987e+00,
+  1.00000262260780914403e+00, 1.00000274181741843904e+00,
+  1.00000286102704194491e+00, 1.00000298023667966163e+00,
+  1.00000309944633158921e+00, 1.00000321865599772764e+00,
+  1.00000333786567807692e+00, 1.00000345707537263706e+00,
+  1.00000357628508140806e+00, 1.00000369549480438991e+00,
+  1.00000381470454158261e+00, 1.00000393391429298617e+00,
+  1.00000405312405860059e+00, 1.00000417233383842586e+00,
+  1.00000429154363246198e+00, 1.00000441075344070896e+00,
+  1.00000452996326316679e+00, 1.00000464917309983548e+00,
+  1.00000476838295071502e+00, 1.00000488759281580542e+00,
+  1.00000500680269510667e+00, 1.00000512601258861878e+00,
+  1.00000524522249634174e+00, 1.00000536443241827556e+00,
+  1.00000548364235442023e+00, 1.00000560285230477575e+00,
+  1.00000572206226934213e+00, 1.00000584127224811937e+00,
+  1.00000596048224110746e+00, 1.00000607969224830640e+00,
+  1.00000619890226971620e+00, 1.00000631811230533685e+00,
+  1.00000643732235516836e+00, 1.00000655653241921073e+00,
+  1.00000667574249746394e+00, 1.00000679495258992802e+00,
+  1.00000691416269660294e+00, 1.00000703337281748873e+00,
+  1.00000715258295258536e+00, 1.00000727179310189285e+00,
+  1.00000739100326541120e+00, 1.00000751021344314040e+00,
+  1.00000000000000000000e+00, 1.00000762942363508046e+00,
+  1.00001525890547848796e+00, 1.00002288844553022251e+00,
+  1.00003051804379095024e+00, 1.00003814770026133729e+00,
+  1.00004577741494138365e+00, 1.00005340718783175546e+00,
+  1.00006103701893311886e+00, 1.00006866690824547383e+00,
+  1.00007629685576948653e+00, 1.00008392686150582307e+00,
+  1.00009155692545448346e+00, 1.00009918704761613384e+00,
+  1.00010681722799144033e+00, 1.00011444746658040295e+00,
+  1.00012207776338368781e+00, 1.00012970811840196106e+00,
+  1.00013733853163522269e+00, 1.00014496900308413885e+00,
+  1.00015259953274937565e+00, 1.00016023012063093311e+00,
+  1.00016786076672947736e+00, 1.00017549147104567453e+00,
+  1.00018312223357952462e+00, 1.00019075305433191581e+00,
+  1.00019838393330284809e+00, 1.00020601487049298761e+00,
+  1.00021364586590300050e+00, 1.00022127691953288675e+00,
+  1.00022890803138353455e+00, 1.00023653920145494389e+00,
+  1.00024417042974778091e+00, 1.00025180171626271175e+00,
+  1.00025943306099973640e+00, 1.00026706446395974304e+00,
+  1.00027469592514273167e+00, 1.00028232744454959047e+00,
+  1.00028995902218031944e+00, 1.00029759065803558471e+00,
+  1.00030522235211605242e+00, 1.00031285410442172257e+00,
+  1.00032048591495348333e+00, 1.00032811778371155675e+00,
+  1.00033574971069616488e+00, 1.00034338169590819589e+00,
+  1.00035101373934764979e+00, 1.00035864584101541475e+00,
+  1.00036627800091149076e+00, 1.00037391021903676602e+00,
+  1.00038154249539146257e+00, 1.00038917482997580244e+00,
+  1.00039680722279067382e+00, 1.00040443967383629875e+00,
+  1.00041207218311289928e+00, 1.00041970475062136359e+00,
+  1.00042733737636191371e+00, 1.00043497006033499375e+00,
+  1.00044260280254104778e+00, 1.00045023560298029786e+00,
+  1.00045786846165363215e+00, 1.00046550137856127272e+00,
+  1.00047313435370366363e+00, 1.00048076738708124900e+00,
+  1.00000000000000000000e+00, 1.00048840047869447289e+00,
+  1.00097703949241645383e+00, 1.00146591715766675179e+00,
+  1.00195503359100279717e+00, 1.00244438890903908579e+00,
+  1.00293398322844673487e+00, 1.00342381666595459322e+00,
+  1.00391388933834746489e+00, 1.00440420136246855165e+00,
+  1.00489475285521656645e+00, 1.00538554393354861993e+00,
+  1.00587657471447822211e+00, 1.00636784531507639251e+00,
+  1.00685935585247099411e+00, 1.00735110644384739942e+00,
+  1.00784309720644804642e+00, 1.00833532825757243856e+00,
+  1.00882779971457803292e+00, 1.00932051169487890796e+00,
+  1.00981346431594687374e+00, 1.01030665769531102782e+00,
+  1.01080009195055753324e+00, 1.01129376719933050666e+00,
+  1.01178768355933157430e+00, 1.01228184114831898377e+00,
+  1.01277624008410960244e+00, 1.01327088048457714109e+00,
+  1.01376576246765282008e+00, 1.01426088615132625748e+00,
+  1.01475625165364347069e+00, 1.01525185909270931894e+00,
+  1.01574770858668572693e+00, 1.01624380025379235093e+00,
+  1.01674013421230657883e+00, 1.01723671058056375216e+00,
+  1.01773352947695694404e+00, 1.01823059101993673714e+00,
+  1.01872789532801233392e+00, 1.01922544251975000229e+00,
+  1.01972323271377418585e+00, 1.02022126602876750390e+00,
+  1.02071954258347008526e+00, 1.02121806249668067856e+00,
+  1.02171682588725554197e+00, 1.02221583287410910934e+00,
+  1.02271508357621376817e+00, 1.02321457811260052573e+00,
+  1.02371431660235789884e+00, 1.02421429916463280207e+00,
+  1.02471452591863054771e+00, 1.02521499698361440167e+00,
+  1.02571571247890602763e+00, 1.02621667252388526492e+00,
+  1.02671787723799012859e+00, 1.02721932674071725344e+00,
+  1.02772102115162167202e+00, 1.02822296059031659254e+00,
+  1.02872514517647339893e+00, 1.02922757502982276101e+00,
+  1.02973025027015285815e+00, 1.03023317101731093359e+00,
+  1.03073633739120262831e+00, 1.03123974951179242510e+00,
+  1.00000000000000000000e+00, 1.03174340749910276038e+00,
+  1.06449445891785954288e+00, 1.09828514030782575794e+00,
+  1.13314845306682632220e+00, 1.16911844616950433284e+00,
+  1.20623024942098067136e+00, 1.24452010776609522935e+00,
+  1.28402541668774139438e+00, 1.32478475872886569675e+00,
+  1.36683794117379631139e+00, 1.41022603492571074746e+00,
+  1.45499141461820125087e+00, 1.50117780000012279729e+00,
+  1.54883029863413312910e+00, 1.59799544995063325104e+00,
+  1.64872127070012819416e+00, 1.70105730184840076014e+00,
+  1.75505465696029849809e+00, 1.81076607211938722664e+00,
+  1.86824595743222232613e+00, 1.92755045016754467113e+00,
+  1.98873746958229191684e+00, 2.05186677348797674725e+00,
+  2.11700001661267478426e+00, 2.18420081081561789915e+00,
+  2.25353478721320854561e+00, 2.32506966027712103084e+00,
+  2.39887529396709808793e+00, 2.47502376996302508871e+00,
+  2.55358945806292680913e+00, 2.63464908881563086851e+00,
+  2.71828182845904553488e+00, 2.80456935623722669604e+00,
+  2.89359594417176113623e+00, 2.98544853936535581340e+00,
+  3.08021684891803104733e+00, 3.17799342753883840018e+00,
+  3.27887376793867346692e+00, 3.38295639409246895468e+00,
+  3.49034295746184142217e+00, 3.60113833627217561073e+00,
+  3.71545073794110392029e+00, 3.83339180475841034834e+00,
+  3.95507672292057721464e+00, 4.08062433502646015882e+00,
+  4.21015725614395996956e+00, 4.34380199356104235164e+00,
+  4.48168907033806451778e+00, 4.62395315278208052234e+00,
+  4.77073318196760265408e+00, 4.92217250943229078786e+00,
+  5.07841903718008147450e+00, 5.23962536212848917216e+00,
+  5.40594892514116676097e+00, 5.57755216479125959239e+00,
+  5.75460267600573072144e+00, 5.93727337374560715233e+00,
+  6.12574266188198635064e+00, 6.32019460743274397174e+00,
+  6.52081912033011246166e+00, 6.72781213889469142941e+00,
+  6.94137582119703555605e+00, 7.16171874249371143151e+00,
+  1.00000000000000000000e+00, 7.38905609893065040694e+00,
+  5.45981500331442362040e+01, 4.03428793492735110249e+02,
+  2.98095798704172830185e+03, 2.20264657948067178950e+04,
+  1.62754791419003915507e+05, 1.20260428416477679275e+06,
+  8.88611052050787210464e+06, 6.56599691373305097222e+07,
+  4.85165195409790277481e+08, 3.58491284613159179688e+09,
+  2.64891221298434715271e+10, 1.95729609428838775635e+11,
+  1.44625706429147509766e+12, 1.06864745815244628906e+13,
+  7.89629601826806875000e+13, 5.83461742527454875000e+14,
+  4.31123154711519500000e+15, 3.18559317571137560000e+16,
+  2.35385266837020000000e+17, 1.73927494152050099200e+18,
+  1.28516001143593082880e+19, 9.49611942060244828160e+19,
+  7.01673591209763143680e+20, 5.18470552858707204506e+21,
+  3.83100800071657691546e+22, 2.83075330327469394756e+23,
+  2.09165949601299610311e+24, 1.54553893559010391826e+25,
+  1.14200738981568423454e+26, 8.43835666874145383188e+26,
+  6.23514908081161674391e+27, 4.60718663433129178064e+28,
+  3.40427604993174075827e+29, 2.51543867091916687979e+30,
+  1.85867174528412788702e+31, 1.37338297954017610775e+32,
+  1.01480038811388874615e+33, 7.49841699699012090701e+33,
+  5.54062238439350983445e+34, 4.09399696212745451138e+35,
+  3.02507732220114256223e+36, 2.23524660373471497416e+37,
+  1.65163625499400180987e+38, 1.22040329431784083418e+39,
+  9.01762840503429851945e+39, 6.66317621641089618500e+40,
+  4.92345828601205826106e+41, 3.63797094760880474988e+42,
+  2.68811714181613560943e+43, 1.98626483613765434356e+44,
+  1.46766223015544238535e+45, 1.08446385529002313207e+46,
+  8.01316426400059069850e+46, 5.92097202766466993617e+47,
+  4.37503944726134096988e+48, 3.23274119108485947460e+49,
+  2.38869060142499127023e+50, 1.76501688569176554670e+51,
+  1.30418087839363225614e+52, 9.63666567360320166416e+52,
+  7.12058632688933793173e+53, 5.26144118266638596909e+54,
+};
+
+/*
+ * EN[k] = exp(-2^(k-5))
+ */
+static const double EN[] = {
+  9.69233234476344129860e-01, 9.39413062813475807644e-01,
+  8.82496902584595455110e-01, 7.78800783071404878477e-01,
+  6.06530659712633424263e-01, 3.67879441171442334024e-01,
+  1.35335283236612702318e-01, 1.83156388887341786686e-02,
+  3.35462627902511853224e-04, 1.12535174719259116458e-07,
+  1.26641655490941755372e-14, 1.60381089054863792659e-28,
+  2.57220937264241481170e-56,
+};
+
+static const float
+  zero	=0.0f,
+  one	=1.0f,
+/* following two terms used when 2^-6 > |x| > 2^-14 */
+  p1	=5.0000000951292138e-01F,
+  p2	=1.6666518897347284e-01F,
+/* big used to force overflow */
+  big	=3.4028234663852885981170E+38F,
+/* tiny used to force underflow */
+  tiny	=1.1754943508222875079688E-38F,
+/* thresh1 is maximum value for x to not overflow */
+  thresh1	=88.72283935546875,
+/* thresh2 is maximum value for -x to not underflow */
+  thresh2	=-103.972076416;
+
+
+float
+EXPF_SPARC (float xf)
+{
+  double w, p, q;
+  int hx, ix, n;
+  float retval;
+  union
+  {
+    int hx_part;
+    float my_xf;
+  } hxx;
+  hxx.my_xf = xf;
+  hx = hxx.hx_part;
+  ix = hx & ~0x80000000;
+
+  if (ix < 0x3c800000)
+    {				/* |x| < 2**-6 */
+      if (ix < 0x38800000)	/* |x| < 2**-14 */
+	return (one + xf);
+      return (one + (xf + (xf * xf) * (p1 + xf * p2)));
+    }
+
+  n = ix >> 23;			/* biased exponent */
+
+  if (n >= 0x85)
+    {				/* |x| >= 2^6 */
+      if (n >= 0x86)
+	{			/* |x| >= 2^7 */
+	  if (n >= 0xff)
+	    {			/* x is nan of +-inf */
+	      if (hx == 0xff800000)
+		return (zero);	/* exp(-inf)=0 */
+	      return (xf * xf);	/* exp(nan/inf) is nan or inf */
+	    }
+	  if (hx > 0)
+	    {
+	      retval = big * big;	/* overflow */
+	      __set_err_expf (hxx.my_xf, retval);
+	      return (retval);
+	    }
+	  else
+	    {
+	      retval = tiny * tiny;	/* underflow */
+	      __set_err_expf (hxx.my_xf, retval);
+	      return (retval);
+	    }
+	}
+      if (hxx.my_xf >= thresh1)
+	{
+	  retval = big * big;	/* overflow */
+	  __set_err_expf (hxx.my_xf, retval);
+	  return (retval);
+	}
+      if (hxx.my_xf <= thresh2)
+	{
+	  retval = tiny * tiny;	/* underflow */
+	  __set_err_expf (hxx.my_xf, retval);
+	  return (retval);
+	}
+    }
+  ix -= n << 23;
+  if (hx > 0)
+    ix += 0x800000;
+  else
+    ix = 0x800000 - ix;
+  if (n >= 0x7f)
+    {				/* n >= 0 */
+      ix <<= n - 0x7f;
+      w = ET[(ix & 0x3f) + 64] * ET[((ix >> 6) & 0x3f) + 128];
+      p = ET[((ix >> 12) & 0x3f) + 192] * ET[((ix >> 18) & 0x3f) + 256];
+      q = ET[((ix >> 24) & 0x3f) + 320];
+    }
+  else
+    {
+      ix <<= n - 0x79;
+      w = ET[ix & 0x3f] * ET[((ix >> 6) & 0x3f) + 64];
+      p = ET[((ix >> 12) & 0x3f) + 128] * ET[((ix >> 18) & 0x3f) + 192];
+      q = ET[((ix >> 24) & 0x3f) + 256];
+    }
+  xf = (float) ((w * p) * (hx < 0 ? q * EN[n - 0x79] : q));
+  return (xf);
+}