glibc/sysdeps/x86/fpu/fenv_private.h

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Split fenv_private.h out of math_private.h more consistently. On some architectures, the parts of math_private.h relating to the floating-point environment are in a separate file fenv_private.h included from math_private.h. As this is purely an architecture-specific convention used by several architectures, however, all such architectures still need their own math_private.h, even if it has nothing to do beyond #include <fenv_private.h> and peculiarity of including the i386 file directly instead of having a shared file in sysdeps/x86. This patch makes the fenv_private.h name an architecture-independent convention in glibc. The include of fenv_private.h from math_private.h becomes architecture-independent (until callers are updated to include fenv_private.h directly so the include from math_private.h is no longer needed). Some architecture math_private.h headers are removed if no longer needed, or renamed to fenv_private.h if all they define belongs in that header; architecture fenv_private.h headers now do require #include_next <fenv_private.h>. The i386 fenv_private.h file moves to sysdeps/x86/fpu/ to reflect how it is actually shared with x86_64. The generic math_private.h gets a new include of <stdbool.h>, as needed for bool in some prototypes in that header (previously that was indirectly included via include/fenv.h, which now only gets included too late in math_private.h, after those prototypes). Tested for x86_64 and x86, and tested with build-many-glibcs.py that installed stripped shared libraries are unchanged by the patch. * sysdeps/aarch64/fpu/fenv_private.h: New file. Based on .... * sysdeps/aarch64/fpu/math_private.h: ... this file. All contents moved to fenv_private.h except for ... (TOINT_INTRINSICS): Kept in math_private.h. (roundtoint): Likewise. (converttoint): Likewise. * sysdeps/arm/fenv_private.h: Change multiple-include guard to [ARM_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/arm/math_private.h: Remove. * sysdeps/generic/fenv_private.h: New file. Contents moved from .... * sysdeps/generic/math_private.h: ... this file. Include <stdbool.h>. Do not include <fenv.h> or <get-rounding-mode.h>. Include <fenv_private.h>. Remove functions and macros moved to fenv_private.h. * sysdeps/i386/fpu/math_private.h: Remove. * sysdeps/mips/math_private.h: Move to .... * sysdeps/mips/fpu/fenv_private.h: ... here. Change multiple-include guard to [MIPS_FENV_PRIVATE_H]. Remove [__mips_hard_float] conditional. Include next <fenv_private.h>. * sysdeps/powerpc/fpu/fenv_private.h: Change multiple-include guard to [POWERPC_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/powerpc/fpu/math_private.h: Do not include <fenv_private.h>. * sysdeps/riscv/rvf/math_private.h: Move to .... * sysdeps/riscv/rvf/fenv_private.h: ... here. Change multiple-include guard to [RISCV_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/sparc/fpu/fenv_private.h: Change multiple-include guard to [SPARC_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/sparc/fpu/math_private.h: Remove. * sysdeps/i386/fpu/fenv_private.h: Move to .... * sysdeps/x86/fpu/fenv_private.h: ... here. Change multiple-include guard to [X86_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/x86_64/fpu/math_private.h: Do not include <sysdeps/i386/fpu/fenv_private.h>.
2018-08-28 20:48:49 +00:00
#ifndef X86_FENV_PRIVATE_H
#define X86_FENV_PRIVATE_H 1
Add float128 support for x86_64, x86. This patch enables float128 support for x86_64 and x86. All GCC versions that can build glibc provide the required support, but since GCC 6 and before don't provide __builtin_nanq / __builtin_nansq, sNaN tests and some tests of NaN payloads need to be disabled with such compilers (this does not affect the generated glibc binaries at all, just the tests). bits/floatn.h declares float128 support to be available for GCC versions that provide the required libgcc support (4.3 for x86_64, 4.4 for i386 GNU/Linux, 4.5 for i386 GNU/Hurd); compilation-only support was present some time before then, but not really useful without the libgcc functions. fenv_private.h needed updating to avoid trying to put _Float128 values in registers. I make no assertion of optimality of the math_opt_barrier / math_force_eval definitions for this case; they are simply intended to be sufficient to work correctly. Tested for x86_64 and x86, with GCC 7 and GCC 6. (Testing for x32 was compilation tests only with build-many-glibcs.py to verify the ABI baseline updates. I have not done any testing for Hurd, although the float128 support is enabled there as for GNU/Linux.) * sysdeps/i386/Implies: Add ieee754/float128. * sysdeps/x86_64/Implies: Likewise. * sysdeps/x86/bits/floatn.h: New file. * sysdeps/x86/float128-abi.h: Likewise. * manual/math.texi (Mathematics): Document support for _Float128 on x86_64 and x86. * sysdeps/i386/fpu/fenv_private.h: Include <bits/floatn.h>. (math_opt_barrier): Do not put _Float128 values in floating-point registers. (math_force_eval): Likewise. [__x86_64__] (SET_RESTORE_ROUNDF128): New macro. * sysdeps/x86/fpu/Makefile [$(subdir) = math] (CPPFLAGS): Append to Makefile variable. * sysdeps/x86/fpu/e_sqrtf128.c: New file. * sysdeps/x86/fpu/sfp-machine.h: Likewise. Based on libgcc. * sysdeps/x86/math-tests.h: New file. * math/libm-test-support.h (XFAIL_FLOAT128_PAYLOAD): New macro. * math/libm-test-getpayload.inc (getpayload_test_data): Use XFAIL_FLOAT128_PAYLOAD. * math/libm-test-setpayload.inc (setpayload_test_data): Likewise. * math/libm-test-totalorder.inc (totalorder_test_data): Likewise. * math/libm-test-totalordermag.inc (totalordermag_test_data): Likewise. * sysdeps/unix/sysv/linux/i386/libc.abilist: Update. * sysdeps/unix/sysv/linux/i386/libm.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/64/libc.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/64/libm.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/x32/libc.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/x32/libm.abilist: Likewise. * sysdeps/i386/fpu/libm-test-ulps: Likewise. * sysdeps/i386/i686/fpu/multiarch/libm-test-ulps: Likewise. * sysdeps/x86_64/fpu/libm-test-ulps: Likewise.
2017-06-26 22:01:27 +00:00
#include <bits/floatn.h>
#include <fenv.h>
#include <fpu_control.h>
/* This file is used by both the 32- and 64-bit ports. The 64-bit port
has a field in the fenv_t for the mxcsr; the 32-bit port does not.
Instead, we (ab)use the only 32-bit field extant in the struct. */
#ifndef __x86_64__
# define __mxcsr __eip
#endif
/* All of these functions are private to libm, and are all used in pairs
to save+change the fp state and restore the original state. Thus we
need not care for both the 387 and the sse unit, only the one we're
actually using. */
#if defined __AVX__ || defined SSE2AVX
# define STMXCSR "vstmxcsr"
# define LDMXCSR "vldmxcsr"
#else
# define STMXCSR "stmxcsr"
# define LDMXCSR "ldmxcsr"
#endif
static __always_inline void
libc_feholdexcept_sse (fenv_t *e)
{
unsigned int mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
e->__mxcsr = mxcsr;
mxcsr = (mxcsr | 0x1f80) & ~0x3f;
asm volatile (LDMXCSR " %0" : : "m" (*&mxcsr));
}
static __always_inline void
libc_feholdexcept_387 (fenv_t *e)
{
/* Recall that fnstenv has a side-effect of masking exceptions.
Clobber all of the fp registers so that the TOS field is 0. */
asm volatile ("fnstenv %0; fnclex"
: "=m"(*e)
: : "st", "st(1)", "st(2)", "st(3)",
"st(4)", "st(5)", "st(6)", "st(7)");
}
static __always_inline void
libc_fesetround_sse (int r)
{
unsigned int mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
mxcsr = (mxcsr & ~0x6000) | (r << 3);
asm volatile (LDMXCSR " %0" : : "m" (*&mxcsr));
}
static __always_inline void
libc_fesetround_387 (int r)
{
fpu_control_t cw;
_FPU_GETCW (cw);
cw = (cw & ~0xc00) | r;
_FPU_SETCW (cw);
}
static __always_inline void
libc_feholdexcept_setround_sse (fenv_t *e, int r)
{
unsigned int mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
e->__mxcsr = mxcsr;
mxcsr = ((mxcsr | 0x1f80) & ~0x603f) | (r << 3);
asm volatile (LDMXCSR " %0" : : "m" (*&mxcsr));
}
/* Set both rounding mode and precision. A convenience function for use
by libc_feholdexcept_setround and libc_feholdexcept_setround_53bit. */
static __always_inline void
libc_feholdexcept_setround_387_prec (fenv_t *e, int r)
{
libc_feholdexcept_387 (e);
fpu_control_t cw = e->__control_word;
cw &= ~(_FPU_RC_ZERO | _FPU_EXTENDED);
cw |= r | 0x3f;
_FPU_SETCW (cw);
}
static __always_inline void
libc_feholdexcept_setround_387 (fenv_t *e, int r)
{
libc_feholdexcept_setround_387_prec (e, r | _FPU_EXTENDED);
}
static __always_inline void
libc_feholdexcept_setround_387_53bit (fenv_t *e, int r)
{
libc_feholdexcept_setround_387_prec (e, r | _FPU_DOUBLE);
}
static __always_inline int
libc_fetestexcept_sse (int e)
{
unsigned int mxcsr;
asm volatile (STMXCSR " %0" : "=m" (*&mxcsr));
return mxcsr & e & FE_ALL_EXCEPT;
}
static __always_inline int
libc_fetestexcept_387 (int ex)
{
fexcept_t temp;
asm volatile ("fnstsw %0" : "=a" (temp));
return temp & ex & FE_ALL_EXCEPT;
}
static __always_inline void
libc_fesetenv_sse (fenv_t *e)
{
asm volatile (LDMXCSR " %0" : : "m" (e->__mxcsr));
}
static __always_inline void
libc_fesetenv_387 (fenv_t *e)
{
/* Clobber all fp registers so that the TOS value we saved earlier is
compatible with the current state of the compiler. */
asm volatile ("fldenv %0"
: : "m" (*e)
: "st", "st(1)", "st(2)", "st(3)",
"st(4)", "st(5)", "st(6)", "st(7)");
}
static __always_inline int
libc_feupdateenv_test_sse (fenv_t *e, int ex)
{
unsigned int mxcsr, old_mxcsr, cur_ex;
asm volatile (STMXCSR " %0" : "=m" (*&mxcsr));
cur_ex = mxcsr & FE_ALL_EXCEPT;
/* Merge current exceptions with the old environment. */
old_mxcsr = e->__mxcsr;
mxcsr = old_mxcsr | cur_ex;
asm volatile (LDMXCSR " %0" : : "m" (*&mxcsr));
/* Raise SIGFPE for any new exceptions since the hold. Expect that
the normal environment has all exceptions masked. */
if (__glibc_unlikely (~(old_mxcsr >> 7) & cur_ex))
__feraiseexcept (cur_ex);
/* Test for exceptions raised since the hold. */
return cur_ex & ex;
}
static __always_inline int
libc_feupdateenv_test_387 (fenv_t *e, int ex)
{
fexcept_t cur_ex;
/* Save current exceptions. */
asm volatile ("fnstsw %0" : "=a" (cur_ex));
cur_ex &= FE_ALL_EXCEPT;
/* Reload original environment. */
libc_fesetenv_387 (e);
/* Merge current exceptions. */
__feraiseexcept (cur_ex);
/* Test for exceptions raised since the hold. */
return cur_ex & ex;
}
static __always_inline void
libc_feupdateenv_sse (fenv_t *e)
{
libc_feupdateenv_test_sse (e, 0);
}
static __always_inline void
libc_feupdateenv_387 (fenv_t *e)
{
libc_feupdateenv_test_387 (e, 0);
}
static __always_inline void
libc_feholdsetround_sse (fenv_t *e, int r)
{
unsigned int mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
e->__mxcsr = mxcsr;
mxcsr = (mxcsr & ~0x6000) | (r << 3);
asm volatile (LDMXCSR " %0" : : "m" (*&mxcsr));
}
static __always_inline void
libc_feholdsetround_387_prec (fenv_t *e, int r)
{
fpu_control_t cw;
_FPU_GETCW (cw);
e->__control_word = cw;
cw &= ~(_FPU_RC_ZERO | _FPU_EXTENDED);
cw |= r;
_FPU_SETCW (cw);
}
static __always_inline void
libc_feholdsetround_387 (fenv_t *e, int r)
{
libc_feholdsetround_387_prec (e, r | _FPU_EXTENDED);
}
static __always_inline void
libc_feholdsetround_387_53bit (fenv_t *e, int r)
{
libc_feholdsetround_387_prec (e, r | _FPU_DOUBLE);
}
static __always_inline void
libc_feresetround_sse (fenv_t *e)
{
unsigned int mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
mxcsr = (mxcsr & ~0x6000) | (e->__mxcsr & 0x6000);
asm volatile (LDMXCSR " %0" : : "m" (*&mxcsr));
}
static __always_inline void
libc_feresetround_387 (fenv_t *e)
{
_FPU_SETCW (e->__control_word);
}
#ifdef __SSE_MATH__
# define libc_feholdexceptf libc_feholdexcept_sse
# define libc_fesetroundf libc_fesetround_sse
# define libc_feholdexcept_setroundf libc_feholdexcept_setround_sse
# define libc_fetestexceptf libc_fetestexcept_sse
# define libc_fesetenvf libc_fesetenv_sse
# define libc_feupdateenv_testf libc_feupdateenv_test_sse
# define libc_feupdateenvf libc_feupdateenv_sse
# define libc_feholdsetroundf libc_feholdsetround_sse
# define libc_feresetroundf libc_feresetround_sse
#else
# define libc_feholdexceptf libc_feholdexcept_387
# define libc_fesetroundf libc_fesetround_387
# define libc_feholdexcept_setroundf libc_feholdexcept_setround_387
# define libc_fetestexceptf libc_fetestexcept_387
# define libc_fesetenvf libc_fesetenv_387
# define libc_feupdateenv_testf libc_feupdateenv_test_387
# define libc_feupdateenvf libc_feupdateenv_387
# define libc_feholdsetroundf libc_feholdsetround_387
# define libc_feresetroundf libc_feresetround_387
#endif /* __SSE_MATH__ */
#ifdef __SSE2_MATH__
# define libc_feholdexcept libc_feholdexcept_sse
# define libc_fesetround libc_fesetround_sse
# define libc_feholdexcept_setround libc_feholdexcept_setround_sse
# define libc_fetestexcept libc_fetestexcept_sse
# define libc_fesetenv libc_fesetenv_sse
# define libc_feupdateenv_test libc_feupdateenv_test_sse
# define libc_feupdateenv libc_feupdateenv_sse
# define libc_feholdsetround libc_feholdsetround_sse
# define libc_feresetround libc_feresetround_sse
#else
# define libc_feholdexcept libc_feholdexcept_387
# define libc_fesetround libc_fesetround_387
# define libc_feholdexcept_setround libc_feholdexcept_setround_387
# define libc_fetestexcept libc_fetestexcept_387
# define libc_fesetenv libc_fesetenv_387
# define libc_feupdateenv_test libc_feupdateenv_test_387
# define libc_feupdateenv libc_feupdateenv_387
# define libc_feholdsetround libc_feholdsetround_387
# define libc_feresetround libc_feresetround_387
#endif /* __SSE2_MATH__ */
#define libc_feholdexceptl libc_feholdexcept_387
#define libc_fesetroundl libc_fesetround_387
#define libc_feholdexcept_setroundl libc_feholdexcept_setround_387
#define libc_fetestexceptl libc_fetestexcept_387
#define libc_fesetenvl libc_fesetenv_387
#define libc_feupdateenv_testl libc_feupdateenv_test_387
#define libc_feupdateenvl libc_feupdateenv_387
#define libc_feholdsetroundl libc_feholdsetround_387
#define libc_feresetroundl libc_feresetround_387
#ifndef __SSE2_MATH__
# define libc_feholdexcept_setround_53bit libc_feholdexcept_setround_387_53bit
# define libc_feholdsetround_53bit libc_feholdsetround_387_53bit
#endif
Add float128 support for x86_64, x86. This patch enables float128 support for x86_64 and x86. All GCC versions that can build glibc provide the required support, but since GCC 6 and before don't provide __builtin_nanq / __builtin_nansq, sNaN tests and some tests of NaN payloads need to be disabled with such compilers (this does not affect the generated glibc binaries at all, just the tests). bits/floatn.h declares float128 support to be available for GCC versions that provide the required libgcc support (4.3 for x86_64, 4.4 for i386 GNU/Linux, 4.5 for i386 GNU/Hurd); compilation-only support was present some time before then, but not really useful without the libgcc functions. fenv_private.h needed updating to avoid trying to put _Float128 values in registers. I make no assertion of optimality of the math_opt_barrier / math_force_eval definitions for this case; they are simply intended to be sufficient to work correctly. Tested for x86_64 and x86, with GCC 7 and GCC 6. (Testing for x32 was compilation tests only with build-many-glibcs.py to verify the ABI baseline updates. I have not done any testing for Hurd, although the float128 support is enabled there as for GNU/Linux.) * sysdeps/i386/Implies: Add ieee754/float128. * sysdeps/x86_64/Implies: Likewise. * sysdeps/x86/bits/floatn.h: New file. * sysdeps/x86/float128-abi.h: Likewise. * manual/math.texi (Mathematics): Document support for _Float128 on x86_64 and x86. * sysdeps/i386/fpu/fenv_private.h: Include <bits/floatn.h>. (math_opt_barrier): Do not put _Float128 values in floating-point registers. (math_force_eval): Likewise. [__x86_64__] (SET_RESTORE_ROUNDF128): New macro. * sysdeps/x86/fpu/Makefile [$(subdir) = math] (CPPFLAGS): Append to Makefile variable. * sysdeps/x86/fpu/e_sqrtf128.c: New file. * sysdeps/x86/fpu/sfp-machine.h: Likewise. Based on libgcc. * sysdeps/x86/math-tests.h: New file. * math/libm-test-support.h (XFAIL_FLOAT128_PAYLOAD): New macro. * math/libm-test-getpayload.inc (getpayload_test_data): Use XFAIL_FLOAT128_PAYLOAD. * math/libm-test-setpayload.inc (setpayload_test_data): Likewise. * math/libm-test-totalorder.inc (totalorder_test_data): Likewise. * math/libm-test-totalordermag.inc (totalordermag_test_data): Likewise. * sysdeps/unix/sysv/linux/i386/libc.abilist: Update. * sysdeps/unix/sysv/linux/i386/libm.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/64/libc.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/64/libm.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/x32/libc.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/x32/libm.abilist: Likewise. * sysdeps/i386/fpu/libm-test-ulps: Likewise. * sysdeps/i386/i686/fpu/multiarch/libm-test-ulps: Likewise. * sysdeps/x86_64/fpu/libm-test-ulps: Likewise.
2017-06-26 22:01:27 +00:00
#ifdef __x86_64__
/* The SSE rounding mode is used by soft-fp (libgcc and glibc) on
x86_64, so that must be set for float128 computations. */
# define SET_RESTORE_ROUNDF128(RM) \
SET_RESTORE_ROUND_GENERIC (RM, libc_feholdsetround_sse, libc_feresetround_sse)
Add build infrastructure for narrowing libm functions. TS 18661-1 defines libm functions that carry out an operation (+ - * / sqrt fma) on their arguments and return a result rounded to a (usually) narrower type, as if the original result were computed to infinite precision and then rounded directly to the result type without any intermediate rounding to the argument type. For example, fadd, faddl and daddl for addition. These are the last remaining TS 18661-1 functions left to be added to glibc. TS 18661-3 extends this to corresponding functions for _FloatN and _FloatNx types. As functions parametrized by two rather than one varying floating-point types, these functions require infrastructure in glibc that was not required for previous libm functions. This patch provides such infrastructure - excluding test support, and actual function implementations, which will be in subsequent patches. Declaring the functions uses a header bits/mathcalls-narrow.h, which is included many times, for each relevant pair of types. This will end up containing macro calls of the form __MATHCALL_NARROW (__MATHCALL_NAME (add), __MATHCALL_REDIR_NAME (add), 2); for each family of narrowing functions. (The structure of this macro call, with the calls to __MATHCALL_NAME and __MATHCALL_REDIR_NAME there rather than in the definition of __MATHCALL_NARROW, arises from the names such as "add" *not* themselves being reserved identifiers - meaning it's necessary to avoid any indirection that would result in a user-defined "add" macro being expanded.) Whereas for existing functions declaring long double functions is disabled if _LIBC in the case where they alias double functions, to facilitate defining the long double functions as aliases of the double ones, there is no such logic for the narrowing functions in this patch. Rather, the files defining such functions are expected to use #define to hide the original declarations of the alias names, to avoid errors about defining aliases with incompatible types. math/Makefile support is added for building the functions (listed in libm-narrow-fns, currently empty) for all relevant pairs of types. An internal header math-narrow.h is added for macros shared between multiple function implementations - currently a ROUND_TO_ODD macro to facilitate writing functions using the round-to-odd implementation approach, and alias macros to create all the required function aliases. libc_feholdexcept_setroundf128 and libc_feupdateenv_testf128 are added for use when required (only for x86_64). float128_private.h support is added for ldbl-128 narrowing functions to be used for _Float128. Certain things are specifically omitted from this patch and the immediate followups. tgmath.h support is deferred; there remain unresolved questions about how the type-generic macros for these functions are supposed to work, especially in the case of arguments of integer type. The math.h / bits/mathcalls-narrow.h logic, and the logic for determining what functions / aliases to define, will need some adjustments to support the sqrt and fma functions, where e.g. f32xsqrtf64 can just be an alias for sqrt rather than a separate function. TS 18661-1 defines FP_FAST_* macros but no support is included for defining them (they won't in general be true without architecture-specific optimized function versions). For each of the function groups (add sub mul div sqrt fma) there are always six functions present (e.g. fadd, faddl, daddl, f32addf64, f32addf32x, f32xaddf64). When _Float64x and _Float128 are supported, there are seven more (e.g. f32addf64x, f32addf128, f64addf64x, f64addf128, f32xaddf64x, f32xaddf128, f64xaddf128). In addition, in the ldbl-opt case there are function names such as __nldbl_daddl (an alias for f32xaddf64, which is not a reserved name in TS 18661-1, only in TS 18661-3), for calls to daddl to be mapped to in the -mlong-double-64 case. (Calls to faddl just get mapped to fadd, and for sqrt and fma there won't be __nldbl_* functions because dsqrtl and dfmal can just be mapped to sqrt and fma with -mlong-double-64.) While there are six or thirteen functions present in each group (plus __nldbl_* names only as an ABI, not an API), not all are distinct; they fall in various groups of aliases. There are two distinct versions built if long double has the same format as double; four if they have distinct formats but there is no _Float64x or _Float128 support; five if long double has binary128 format; seven when _Float128 is distinct from long double. Architecture-specific optimized versions are possible, but not included in my patches. For example, IA64 generally supports narrowing the result of most floating-point instructions; Power ISA 2.07 (POWER8) supports double values as arguments to float instructions, with the results narrowed as expected; Power ISA 3 (POWER9) supports round-to-odd for float128 instructions, so meaning that approach can be used without needing to set and restore the rounding mode and test "inexact". I intend to leave any such optimized versions to the architecture maintainers. Generally in such cases it would also make sense for calls to these functions to be expanded inline (given -fno-math-errno); I put a suggestion for TS 18661-1 built-in functions at <https://gcc.gnu.org/wiki/SummerOfCode>. Tested for x86_64 (this patch in isolation, as well as testing for various configurations in conjunction with further patches). * math/bits/mathcalls-narrow.h: New file. * include/bits/mathcalls-narrow.h: Likewise. * math/math-narrow.h: Likewise. * math/math.h (__MATHCALL_NARROW_ARGS_1): New macro. (__MATHCALL_NARROW_ARGS_2): Likewise. (__MATHCALL_NARROW_ARGS_3): Likewise. (__MATHCALL_NARROW_NORMAL): Likewise. (__MATHCALL_NARROW_REDIR): Likewise. (__MATHCALL_NARROW): Likewise. [__GLIBC_USE (IEC_60559_BFP_EXT)]: Repeatedly include <bits/mathcalls-narrow.h> with _Mret_, _Marg_ and __MATHCALL_NAME defined. [__GLIBC_USE (IEC_60559_TYPES_EXT)]: Likewise. * math/Makefile (headers): Add bits/mathcalls-narrow.h. (libm-narrow-fns): New variable. (libm-narrow-types-basic): Likewise. (libm-narrow-types-ldouble-yes): Likewise. (libm-narrow-types-float128-yes): Likewise. (libm-narrow-types-float128-alias-yes): Likewise. (libm-narrow-types): Likewise. (libm-routines): Add narrowing functions. * sysdeps/i386/fpu/fenv_private.h [__x86_64__] (libc_feholdexcept_setroundf128): New macro. [__x86_64__] (libc_feupdateenv_testf128): Likewise. * sysdeps/ieee754/float128/float128_private.h: Include <math/math-narrow.h>. [libc_feholdexcept_setroundf128] (libc_feholdexcept_setroundl): Undefine and redefine. [libc_feupdateenv_testf128] (libc_feupdateenv_testl): Likewise. (libm_alias_float_ldouble): Undefine and redefine. (libm_alias_double_ldouble): Likewise.
2018-02-09 21:18:52 +00:00
# define libc_feholdexcept_setroundf128 libc_feholdexcept_setround_sse
# define libc_feupdateenv_testf128 libc_feupdateenv_test_sse
#else
/* The 387 rounding mode is used by soft-fp for 32-bit, but whether
387 or SSE exceptions are used depends on whether libgcc was built
for SSE math, which is not known when glibc is being built. */
# define libc_feholdexcept_setroundf128 default_libc_feholdexcept_setround
# define libc_feupdateenv_testf128 default_libc_feupdateenv_test
Add float128 support for x86_64, x86. This patch enables float128 support for x86_64 and x86. All GCC versions that can build glibc provide the required support, but since GCC 6 and before don't provide __builtin_nanq / __builtin_nansq, sNaN tests and some tests of NaN payloads need to be disabled with such compilers (this does not affect the generated glibc binaries at all, just the tests). bits/floatn.h declares float128 support to be available for GCC versions that provide the required libgcc support (4.3 for x86_64, 4.4 for i386 GNU/Linux, 4.5 for i386 GNU/Hurd); compilation-only support was present some time before then, but not really useful without the libgcc functions. fenv_private.h needed updating to avoid trying to put _Float128 values in registers. I make no assertion of optimality of the math_opt_barrier / math_force_eval definitions for this case; they are simply intended to be sufficient to work correctly. Tested for x86_64 and x86, with GCC 7 and GCC 6. (Testing for x32 was compilation tests only with build-many-glibcs.py to verify the ABI baseline updates. I have not done any testing for Hurd, although the float128 support is enabled there as for GNU/Linux.) * sysdeps/i386/Implies: Add ieee754/float128. * sysdeps/x86_64/Implies: Likewise. * sysdeps/x86/bits/floatn.h: New file. * sysdeps/x86/float128-abi.h: Likewise. * manual/math.texi (Mathematics): Document support for _Float128 on x86_64 and x86. * sysdeps/i386/fpu/fenv_private.h: Include <bits/floatn.h>. (math_opt_barrier): Do not put _Float128 values in floating-point registers. (math_force_eval): Likewise. [__x86_64__] (SET_RESTORE_ROUNDF128): New macro. * sysdeps/x86/fpu/Makefile [$(subdir) = math] (CPPFLAGS): Append to Makefile variable. * sysdeps/x86/fpu/e_sqrtf128.c: New file. * sysdeps/x86/fpu/sfp-machine.h: Likewise. Based on libgcc. * sysdeps/x86/math-tests.h: New file. * math/libm-test-support.h (XFAIL_FLOAT128_PAYLOAD): New macro. * math/libm-test-getpayload.inc (getpayload_test_data): Use XFAIL_FLOAT128_PAYLOAD. * math/libm-test-setpayload.inc (setpayload_test_data): Likewise. * math/libm-test-totalorder.inc (totalorder_test_data): Likewise. * math/libm-test-totalordermag.inc (totalordermag_test_data): Likewise. * sysdeps/unix/sysv/linux/i386/libc.abilist: Update. * sysdeps/unix/sysv/linux/i386/libm.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/64/libc.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/64/libm.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/x32/libc.abilist: Likewise. * sysdeps/unix/sysv/linux/x86_64/x32/libm.abilist: Likewise. * sysdeps/i386/fpu/libm-test-ulps: Likewise. * sysdeps/i386/i686/fpu/multiarch/libm-test-ulps: Likewise. * sysdeps/x86_64/fpu/libm-test-ulps: Likewise.
2017-06-26 22:01:27 +00:00
#endif
Set/restore rounding mode only when needed The most common use case of math functions is with default rounding mode, i.e. rounding to nearest. Setting and restoring rounding mode is an unnecessary overhead for this, so I've added support for a context, which does the set/restore only if the FP status needs a change. The code is written such that only x86 uses these. Other architectures should be unaffected by it, but would definitely benefit if the set/restore has as much overhead relative to the rest of the code, as the x86 bits do. Here's a summary of the performance improvement due to these improvements; I've only mentioned functions that use the set/restore and have benchmark inputs for x86_64: Before: cos(): ITERS:4.69335e+08: TOTAL:28884.6Mcy, MAX:4080.28cy, MIN:57.562cy, 16248.6 calls/Mcy exp(): ITERS:4.47604e+08: TOTAL:28796.2Mcy, MAX:207.721cy, MIN:62.385cy, 15543.9 calls/Mcy pow(): ITERS:1.63485e+08: TOTAL:28879.9Mcy, MAX:362.255cy, MIN:172.469cy, 5660.86 calls/Mcy sin(): ITERS:3.89578e+08: TOTAL:28900Mcy, MAX:704.859cy, MIN:47.583cy, 13480.2 calls/Mcy tan(): ITERS:7.0971e+07: TOTAL:28902.2Mcy, MAX:1357.79cy, MIN:388.58cy, 2455.55 calls/Mcy After: cos(): ITERS:6.0014e+08: TOTAL:28875.9Mcy, MAX:364.283cy, MIN:45.716cy, 20783.4 calls/Mcy exp(): ITERS:5.48578e+08: TOTAL:28764.9Mcy, MAX:191.617cy, MIN:51.011cy, 19071.1 calls/Mcy pow(): ITERS:1.70013e+08: TOTAL:28873.6Mcy, MAX:689.522cy, MIN:163.989cy, 5888.18 calls/Mcy sin(): ITERS:4.64079e+08: TOTAL:28891.5Mcy, MAX:6959.3cy, MIN:36.189cy, 16062.8 calls/Mcy tan(): ITERS:7.2354e+07: TOTAL:28898.9Mcy, MAX:1295.57cy, MIN:380.698cy, 2503.7 calls/Mcy So the improvements are: cos: 27.9089% exp: 22.6919% pow: 4.01564% sin: 19.1585% tan: 1.96086% The downside of the change is that it will have an adverse performance impact on non-default rounding modes, but I think the tradeoff is justified.
2013-06-12 05:06:48 +00:00
/* We have support for rounding mode context. */
#define HAVE_RM_CTX 1
static __always_inline void
libc_feholdexcept_setround_sse_ctx (struct rm_ctx *ctx, int r)
{
unsigned int mxcsr, new_mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
new_mxcsr = ((mxcsr | 0x1f80) & ~0x603f) | (r << 3);
ctx->env.__mxcsr = mxcsr;
if (__glibc_unlikely (mxcsr != new_mxcsr))
{
asm volatile (LDMXCSR " %0" : : "m" (*&new_mxcsr));
ctx->updated_status = true;
}
else
ctx->updated_status = false;
}
/* Unconditional since we want to overwrite any exceptions that occurred in the
context. This is also why all fehold* functions unconditionally write into
ctx->env. */
static __always_inline void
libc_fesetenv_sse_ctx (struct rm_ctx *ctx)
{
libc_fesetenv_sse (&ctx->env);
}
static __always_inline void
libc_feupdateenv_sse_ctx (struct rm_ctx *ctx)
{
if (__glibc_unlikely (ctx->updated_status))
libc_feupdateenv_test_sse (&ctx->env, 0);
}
static __always_inline void
libc_feholdexcept_setround_387_prec_ctx (struct rm_ctx *ctx, int r)
{
libc_feholdexcept_387 (&ctx->env);
fpu_control_t cw = ctx->env.__control_word;
fpu_control_t old_cw = cw;
cw &= ~(_FPU_RC_ZERO | _FPU_EXTENDED);
cw |= r | 0x3f;
if (__glibc_unlikely (old_cw != cw))
{
_FPU_SETCW (cw);
ctx->updated_status = true;
}
else
ctx->updated_status = false;
}
static __always_inline void
libc_feholdexcept_setround_387_ctx (struct rm_ctx *ctx, int r)
{
libc_feholdexcept_setround_387_prec_ctx (ctx, r | _FPU_EXTENDED);
}
static __always_inline void
libc_feholdexcept_setround_387_53bit_ctx (struct rm_ctx *ctx, int r)
{
libc_feholdexcept_setround_387_prec_ctx (ctx, r | _FPU_DOUBLE);
}
static __always_inline void
libc_feholdsetround_387_prec_ctx (struct rm_ctx *ctx, int r)
{
fpu_control_t cw, new_cw;
_FPU_GETCW (cw);
new_cw = cw;
new_cw &= ~(_FPU_RC_ZERO | _FPU_EXTENDED);
new_cw |= r;
ctx->env.__control_word = cw;
if (__glibc_unlikely (new_cw != cw))
{
_FPU_SETCW (new_cw);
ctx->updated_status = true;
}
else
ctx->updated_status = false;
}
static __always_inline void
libc_feholdsetround_387_ctx (struct rm_ctx *ctx, int r)
{
libc_feholdsetround_387_prec_ctx (ctx, r | _FPU_EXTENDED);
}
static __always_inline void
libc_feholdsetround_387_53bit_ctx (struct rm_ctx *ctx, int r)
{
libc_feholdsetround_387_prec_ctx (ctx, r | _FPU_DOUBLE);
}
static __always_inline void
libc_feholdsetround_sse_ctx (struct rm_ctx *ctx, int r)
{
unsigned int mxcsr, new_mxcsr;
asm (STMXCSR " %0" : "=m" (*&mxcsr));
new_mxcsr = (mxcsr & ~0x6000) | (r << 3);
ctx->env.__mxcsr = mxcsr;
if (__glibc_unlikely (new_mxcsr != mxcsr))
{
asm volatile (LDMXCSR " %0" : : "m" (*&new_mxcsr));
ctx->updated_status = true;
}
else
ctx->updated_status = false;
}
static __always_inline void
libc_feresetround_sse_ctx (struct rm_ctx *ctx)
{
if (__glibc_unlikely (ctx->updated_status))
libc_feresetround_sse (&ctx->env);
}
static __always_inline void
libc_feresetround_387_ctx (struct rm_ctx *ctx)
{
if (__glibc_unlikely (ctx->updated_status))
_FPU_SETCW (ctx->env.__control_word);
}
static __always_inline void
libc_feupdateenv_387_ctx (struct rm_ctx *ctx)
{
if (__glibc_unlikely (ctx->updated_status))
libc_feupdateenv_test_387 (&ctx->env, 0);
}
#ifdef __SSE_MATH__
# define libc_feholdexcept_setroundf_ctx libc_feholdexcept_setround_sse_ctx
# define libc_fesetenvf_ctx libc_fesetenv_sse_ctx
# define libc_feupdateenvf_ctx libc_feupdateenv_sse_ctx
# define libc_feholdsetroundf_ctx libc_feholdsetround_sse_ctx
# define libc_feresetroundf_ctx libc_feresetround_sse_ctx
#else
# define libc_feholdexcept_setroundf_ctx libc_feholdexcept_setround_387_ctx
# define libc_feupdateenvf_ctx libc_feupdateenv_387_ctx
# define libc_feholdsetroundf_ctx libc_feholdsetround_387_ctx
# define libc_feresetroundf_ctx libc_feresetround_387_ctx
#endif /* __SSE_MATH__ */
#ifdef __SSE2_MATH__
# if defined (__x86_64__) || !defined (MATH_SET_BOTH_ROUNDING_MODES)
# define libc_feholdexcept_setround_ctx libc_feholdexcept_setround_sse_ctx
# define libc_fesetenv_ctx libc_fesetenv_sse_ctx
# define libc_feupdateenv_ctx libc_feupdateenv_sse_ctx
# define libc_feholdsetround_ctx libc_feholdsetround_sse_ctx
# define libc_feresetround_ctx libc_feresetround_sse_ctx
# else
# define libc_feholdexcept_setround_ctx default_libc_feholdexcept_setround_ctx
# define libc_fesetenv_ctx default_libc_fesetenv_ctx
# define libc_feupdateenv_ctx default_libc_feupdateenv_ctx
# define libc_feholdsetround_ctx default_libc_feholdsetround_ctx
# define libc_feresetround_ctx default_libc_feresetround_ctx
# endif
Set/restore rounding mode only when needed The most common use case of math functions is with default rounding mode, i.e. rounding to nearest. Setting and restoring rounding mode is an unnecessary overhead for this, so I've added support for a context, which does the set/restore only if the FP status needs a change. The code is written such that only x86 uses these. Other architectures should be unaffected by it, but would definitely benefit if the set/restore has as much overhead relative to the rest of the code, as the x86 bits do. Here's a summary of the performance improvement due to these improvements; I've only mentioned functions that use the set/restore and have benchmark inputs for x86_64: Before: cos(): ITERS:4.69335e+08: TOTAL:28884.6Mcy, MAX:4080.28cy, MIN:57.562cy, 16248.6 calls/Mcy exp(): ITERS:4.47604e+08: TOTAL:28796.2Mcy, MAX:207.721cy, MIN:62.385cy, 15543.9 calls/Mcy pow(): ITERS:1.63485e+08: TOTAL:28879.9Mcy, MAX:362.255cy, MIN:172.469cy, 5660.86 calls/Mcy sin(): ITERS:3.89578e+08: TOTAL:28900Mcy, MAX:704.859cy, MIN:47.583cy, 13480.2 calls/Mcy tan(): ITERS:7.0971e+07: TOTAL:28902.2Mcy, MAX:1357.79cy, MIN:388.58cy, 2455.55 calls/Mcy After: cos(): ITERS:6.0014e+08: TOTAL:28875.9Mcy, MAX:364.283cy, MIN:45.716cy, 20783.4 calls/Mcy exp(): ITERS:5.48578e+08: TOTAL:28764.9Mcy, MAX:191.617cy, MIN:51.011cy, 19071.1 calls/Mcy pow(): ITERS:1.70013e+08: TOTAL:28873.6Mcy, MAX:689.522cy, MIN:163.989cy, 5888.18 calls/Mcy sin(): ITERS:4.64079e+08: TOTAL:28891.5Mcy, MAX:6959.3cy, MIN:36.189cy, 16062.8 calls/Mcy tan(): ITERS:7.2354e+07: TOTAL:28898.9Mcy, MAX:1295.57cy, MIN:380.698cy, 2503.7 calls/Mcy So the improvements are: cos: 27.9089% exp: 22.6919% pow: 4.01564% sin: 19.1585% tan: 1.96086% The downside of the change is that it will have an adverse performance impact on non-default rounding modes, but I think the tradeoff is justified.
2013-06-12 05:06:48 +00:00
#else
# define libc_feholdexcept_setround_ctx libc_feholdexcept_setround_387_ctx
# define libc_feupdateenv_ctx libc_feupdateenv_387_ctx
Fix yn overflow handling in non-default rounding modes (bug 16561, bug 16562). This patch fixes bugs 16561 and 16562, bad results of yn in overflow cases in non-default rounding modes, both because an intermediate overflow in the recurrence does not get detected if the result is not an infinity and because an overflowing result may occur in the wrong sign. The fix is to set FE_TONEAREST mode internally for the parts of the function where such overflows can occur (which includes the call to y1 - where yn is used to compute a Bessel function of order -1, negating the result of y1 isn't correct for overflowing results in directed rounding modes) and then compute an overflowing value in the original rounding mode if the to-nearest result was an infinity. Tested x86_64 and x86 and ulps updated accordingly. Also tested for mips64 and powerpc32 to test the ldbl-128 and ldbl-128ibm changes. (The tests for these bugs were added in my previous y1 patch, so the only thing this patch has to do with the testsuite is enable yn testing in all rounding modes.) [BZ #16561] [BZ #16562] * sysdeps/ieee754/dbl-64/e_jn.c: Include <float.h>. (__ieee754_yn): Set FE_TONEAREST mode internally and then recompute overflowing results in original rounding mode. * sysdeps/ieee754/flt-32/e_jnf.c: Include <float.h>. (__ieee754_ynf): Set FE_TONEAREST mode internally and then recompute overflowing results in original rounding mode. * sysdeps/ieee754/ldbl-128/e_jnl.c: Include <float.h>. (__ieee754_ynl): Set FE_TONEAREST mode internally and then recompute overflowing results in original rounding mode. * sysdeps/ieee754/ldbl-128ibm/e_jnl.c: Include <float.h>. (__ieee754_ynl): Set FE_TONEAREST mode internally and then recompute overflowing results in original rounding mode. * sysdeps/ieee754/ldbl-96/e_jnl.c: Include <float.h>. (__ieee754_ynl): Set FE_TONEAREST mode internally and then recompute overflowing results in original rounding mode. * sysdeps/i386/fpu/fenv_private.h [!__SSE2_MATH__] (libc_feholdsetround_ctx): New macro. * math/libm-test.inc (yn_test): Use ALL_RM_TEST. * sysdeps/i386/fpu/libm-test-ulps: Update. * sysdeps/x86_64/fpu/libm-test-ulps : Likewise.
2014-06-27 14:52:13 +00:00
# define libc_feholdsetround_ctx libc_feholdsetround_387_ctx
Set/restore rounding mode only when needed The most common use case of math functions is with default rounding mode, i.e. rounding to nearest. Setting and restoring rounding mode is an unnecessary overhead for this, so I've added support for a context, which does the set/restore only if the FP status needs a change. The code is written such that only x86 uses these. Other architectures should be unaffected by it, but would definitely benefit if the set/restore has as much overhead relative to the rest of the code, as the x86 bits do. Here's a summary of the performance improvement due to these improvements; I've only mentioned functions that use the set/restore and have benchmark inputs for x86_64: Before: cos(): ITERS:4.69335e+08: TOTAL:28884.6Mcy, MAX:4080.28cy, MIN:57.562cy, 16248.6 calls/Mcy exp(): ITERS:4.47604e+08: TOTAL:28796.2Mcy, MAX:207.721cy, MIN:62.385cy, 15543.9 calls/Mcy pow(): ITERS:1.63485e+08: TOTAL:28879.9Mcy, MAX:362.255cy, MIN:172.469cy, 5660.86 calls/Mcy sin(): ITERS:3.89578e+08: TOTAL:28900Mcy, MAX:704.859cy, MIN:47.583cy, 13480.2 calls/Mcy tan(): ITERS:7.0971e+07: TOTAL:28902.2Mcy, MAX:1357.79cy, MIN:388.58cy, 2455.55 calls/Mcy After: cos(): ITERS:6.0014e+08: TOTAL:28875.9Mcy, MAX:364.283cy, MIN:45.716cy, 20783.4 calls/Mcy exp(): ITERS:5.48578e+08: TOTAL:28764.9Mcy, MAX:191.617cy, MIN:51.011cy, 19071.1 calls/Mcy pow(): ITERS:1.70013e+08: TOTAL:28873.6Mcy, MAX:689.522cy, MIN:163.989cy, 5888.18 calls/Mcy sin(): ITERS:4.64079e+08: TOTAL:28891.5Mcy, MAX:6959.3cy, MIN:36.189cy, 16062.8 calls/Mcy tan(): ITERS:7.2354e+07: TOTAL:28898.9Mcy, MAX:1295.57cy, MIN:380.698cy, 2503.7 calls/Mcy So the improvements are: cos: 27.9089% exp: 22.6919% pow: 4.01564% sin: 19.1585% tan: 1.96086% The downside of the change is that it will have an adverse performance impact on non-default rounding modes, but I think the tradeoff is justified.
2013-06-12 05:06:48 +00:00
# define libc_feresetround_ctx libc_feresetround_387_ctx
#endif /* __SSE2_MATH__ */
#define libc_feholdexcept_setroundl_ctx libc_feholdexcept_setround_387_ctx
#define libc_feupdateenvl_ctx libc_feupdateenv_387_ctx
#define libc_feholdsetroundl_ctx libc_feholdsetround_387_ctx
#define libc_feresetroundl_ctx libc_feresetround_387_ctx
#ifndef __SSE2_MATH__
# define libc_feholdsetround_53bit_ctx libc_feholdsetround_387_53bit_ctx
# define libc_feresetround_53bit_ctx libc_feresetround_387_ctx
#endif
#undef __mxcsr
Split fenv_private.h out of math_private.h more consistently. On some architectures, the parts of math_private.h relating to the floating-point environment are in a separate file fenv_private.h included from math_private.h. As this is purely an architecture-specific convention used by several architectures, however, all such architectures still need their own math_private.h, even if it has nothing to do beyond #include <fenv_private.h> and peculiarity of including the i386 file directly instead of having a shared file in sysdeps/x86. This patch makes the fenv_private.h name an architecture-independent convention in glibc. The include of fenv_private.h from math_private.h becomes architecture-independent (until callers are updated to include fenv_private.h directly so the include from math_private.h is no longer needed). Some architecture math_private.h headers are removed if no longer needed, or renamed to fenv_private.h if all they define belongs in that header; architecture fenv_private.h headers now do require #include_next <fenv_private.h>. The i386 fenv_private.h file moves to sysdeps/x86/fpu/ to reflect how it is actually shared with x86_64. The generic math_private.h gets a new include of <stdbool.h>, as needed for bool in some prototypes in that header (previously that was indirectly included via include/fenv.h, which now only gets included too late in math_private.h, after those prototypes). Tested for x86_64 and x86, and tested with build-many-glibcs.py that installed stripped shared libraries are unchanged by the patch. * sysdeps/aarch64/fpu/fenv_private.h: New file. Based on .... * sysdeps/aarch64/fpu/math_private.h: ... this file. All contents moved to fenv_private.h except for ... (TOINT_INTRINSICS): Kept in math_private.h. (roundtoint): Likewise. (converttoint): Likewise. * sysdeps/arm/fenv_private.h: Change multiple-include guard to [ARM_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/arm/math_private.h: Remove. * sysdeps/generic/fenv_private.h: New file. Contents moved from .... * sysdeps/generic/math_private.h: ... this file. Include <stdbool.h>. Do not include <fenv.h> or <get-rounding-mode.h>. Include <fenv_private.h>. Remove functions and macros moved to fenv_private.h. * sysdeps/i386/fpu/math_private.h: Remove. * sysdeps/mips/math_private.h: Move to .... * sysdeps/mips/fpu/fenv_private.h: ... here. Change multiple-include guard to [MIPS_FENV_PRIVATE_H]. Remove [__mips_hard_float] conditional. Include next <fenv_private.h>. * sysdeps/powerpc/fpu/fenv_private.h: Change multiple-include guard to [POWERPC_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/powerpc/fpu/math_private.h: Do not include <fenv_private.h>. * sysdeps/riscv/rvf/math_private.h: Move to .... * sysdeps/riscv/rvf/fenv_private.h: ... here. Change multiple-include guard to [RISCV_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/sparc/fpu/fenv_private.h: Change multiple-include guard to [SPARC_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/sparc/fpu/math_private.h: Remove. * sysdeps/i386/fpu/fenv_private.h: Move to .... * sysdeps/x86/fpu/fenv_private.h: ... here. Change multiple-include guard to [X86_FENV_PRIVATE_H]. Include next <fenv_private.h>. * sysdeps/x86_64/fpu/math_private.h: Do not include <sysdeps/i386/fpu/fenv_private.h>.
2018-08-28 20:48:49 +00:00
#include_next <fenv_private.h>
#endif /* X86_FENV_PRIVATE_H */