newlib-cygwin/winsup/cygwin/fenv.cc

467 lines
14 KiB
C++

/* fenv.cc
This file is part of Cygwin.
This software is a copyrighted work licensed under the terms of the
Cygwin license. Please consult the file "CYGWIN_LICENSE" for
details. */
#include "winsup.h"
#include "fenv.h"
#include "errno.h"
#include "wincap.h"
#include <string.h>
/* x87 supports subnormal numbers so we need it below. */
#define __FE_DENORM (1 << 1)
/* mask (= 0x3f) to disable all exceptions at initialization */
#define __FE_ALL_EXCEPT_X86 (FE_ALL_EXCEPT | __FE_DENORM)
/* Mask and shift amount for rounding bits. */
#define FE_CW_ROUND_MASK (0x0c00)
#define FE_CW_ROUND_SHIFT (10)
/* Same, for SSE MXCSR. */
#define FE_MXCSR_ROUND_MASK (0x6000)
#define FE_MXCSR_ROUND_SHIFT (13)
/* Mask and shift amount for precision bits. */
#define FE_CW_PREC_MASK (0x0300)
#define FE_CW_PREC_SHIFT (8)
/* In x87, exception status bits and mask bits occupy
corresponding bit positions in the status and control
registers, respectively. In SSE, they are both located
in the control-and-status register, with the status bits
corresponding to the x87 positions, and the mask bits
shifted by this amount to the left. */
#define FE_SSE_EXCEPT_MASK_SHIFT (7)
/* These are writable so we can initialise them at startup. */
static fenv_t fe_nomask_env;
/* These pointers provide the outside world with read-only access to them. */
const fenv_t *_fe_nomask_env = &fe_nomask_env;
/* Although Cygwin assumes i686 or above (hence SSE available) these
days, and the compiler feels free to use it (depending on compile-
time flags of course), we should avoid needlessly breaking any
purely integer mode apps (or apps compiled with -mno-sse), so we
only manage SSE state in this fenv module if we detect that SSE
instructions are available at runtime. If we didn't do this, all
applications run on older machines would bomb out with an invalid
instruction exception right at startup; let's not be *that* WJM! */
static bool use_sse = false;
/* This function enables traps for each of the exceptions as indicated
by the parameter except. The individual exceptions are described in
[ ... glibc manual xref elided ...]. Only the specified exceptions are
enabled, the status of the other exceptions is not changed.
The function returns the previous enabled exceptions in case the
operation was successful, -1 otherwise. */
int
feenableexcept (int excepts)
{
unsigned short cw, old_cw;
unsigned int mxcsr = 0;
if (excepts & ~FE_ALL_EXCEPT)
return -1;
/* Get control words. */
__asm__ volatile ("fnstcw %0" : "=m" (old_cw) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (mxcsr) : );
/* Enable exceptions by clearing mask bits. */
cw = old_cw & ~excepts;
mxcsr &= ~(excepts << FE_SSE_EXCEPT_MASK_SHIFT);
/* Store updated control words. */
__asm__ volatile ("fldcw %0" :: "m" (cw));
if (use_sse)
__asm__ volatile ("ldmxcsr %0" :: "m" (mxcsr));
/* Return old value. We assume SSE and x87 stay in sync. Note that
we are returning a mask of enabled exceptions, which is the opposite
of the flags in the register, which are set to disable (mask) their
related exceptions. */
return (~old_cw) & FE_ALL_EXCEPT;
}
/* This function disables traps for each of the exceptions as indicated
by the parameter except. The individual exceptions are described in
[ ... glibc manual xref elided ...]. Only the specified exceptions are
disabled, the status of the other exceptions is not changed.
The function returns the previous enabled exceptions in case the
operation was successful, -1 otherwise. */
int
fedisableexcept (int excepts)
{
unsigned short cw, old_cw;
unsigned int mxcsr = 0;
if (excepts & ~FE_ALL_EXCEPT)
return -1;
/* Get control words. */
__asm__ volatile ("fnstcw %0" : "=m" (old_cw) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (mxcsr) : );
/* Disable exceptions by setting mask bits. */
cw = old_cw | excepts;
mxcsr |= (excepts << FE_SSE_EXCEPT_MASK_SHIFT);
/* Store updated control words. */
__asm__ volatile ("fldcw %0" :: "m" (cw));
if (use_sse)
__asm__ volatile ("ldmxcsr %0" :: "m" (mxcsr));
/* Return old value. We assume SSE and x87 stay in sync. Note that
we are returning a mask of enabled exceptions, which is the opposite
of the flags in the register, which are set to disable (mask) their
related exceptions. */
return (~old_cw) & FE_ALL_EXCEPT;
}
/* This function returns a bitmask of all currently enabled exceptions. It
returns -1 in case of failure. */
int
fegetexcept (void)
{
unsigned short cw;
/* Get control word. We assume SSE and x87 stay in sync. */
__asm__ volatile ("fnstcw %0" : "=m" (cw) : );
/* Exception is *dis*abled when mask bit is set. */
return (~cw) & FE_ALL_EXCEPT;
}
/* Store the floating-point environment in the variable pointed to by envp.
The function returns zero in case the operation was successful, a non-zero
value otherwise. */
int
fegetenv (fenv_t *envp)
{
/* fnstenv disables all exceptions in the x87 FPU; as this is not what is
desired here, reload the cfg saved from the x87 FPU, back to the FPU */
__asm__ volatile ("fnstenv %0\n\
fldenv %0"
: "=m" (envp->_fpu) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (envp->_sse_mxcsr) : );
return 0;
}
/* Store the current floating-point environment in the object pointed to
by envp. Then clear all exception flags, and set the FPU to trap no
exceptions. Not all FPUs support trapping no exceptions; if feholdexcept
cannot set this mode, it returns nonzero value. If it succeeds, it
returns zero. */
int
feholdexcept (fenv_t *envp)
{
unsigned int mxcsr;
fegetenv (envp);
mxcsr = envp->_sse_mxcsr & ~FE_ALL_EXCEPT;
if (use_sse)
__asm__ volatile ("ldmxcsr %0" :: "m" (mxcsr));
__asm__ volatile ("fnclex");
fedisableexcept (FE_ALL_EXCEPT);
return 0;
}
/* Set the floating-point environment to that described by envp. The
function returns zero in case the operation was successful, a non-zero
value otherwise. */
int
fesetenv (const fenv_t *envp)
{
__asm__ volatile ("fldenv %0" :: "m" (envp->_fpu) );
if (use_sse)
__asm__ volatile ("ldmxcsr %0" :: "m" (envp->_sse_mxcsr));
return 0;
}
/* Like fesetenv, this function sets the floating-point environment to
that described by envp. However, if any exceptions were flagged in the
status word before feupdateenv was called, they remain flagged after
the call. In other words, after feupdateenv is called, the status
word is the bitwise OR of the previous status word and the one saved
in envp. The function returns zero in case the operation was successful,
a non-zero value otherwise. */
int
feupdateenv (const fenv_t *envp)
{
fenv_t envcopy;
unsigned int mxcsr = 0;
unsigned short sw;
/* Don't want to modify *envp, but want to update environment atomically,
so take a copy and merge the existing exceptions into it. */
memcpy (&envcopy, envp, sizeof *envp);
__asm__ volatile ("fnstsw %0" : "=m" (sw) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (mxcsr) : );
envcopy._fpu._fpu_sw |= (sw & FE_ALL_EXCEPT);
envcopy._sse_mxcsr |= (mxcsr & FE_ALL_EXCEPT);
return fesetenv (&envcopy);
}
/* This function clears all of the supported exception flags indicated by
excepts. The function returns zero in case the operation was successful,
a non-zero value otherwise. */
int
feclearexcept (int excepts)
{
fenv_t fenv;
if (excepts & ~FE_ALL_EXCEPT)
return EINVAL;
/* Need to save/restore whole environment to modify status word. */
fegetenv (&fenv);
/* Mask undesired bits out. */
fenv._fpu._fpu_sw &= ~excepts;
fenv._sse_mxcsr &= ~excepts;
/* Set back into FPU state. */
return fesetenv (&fenv);
}
/* This function raises the supported exceptions indicated by
excepts. If more than one exception bit in excepts is set the order
in which the exceptions are raised is undefined except that overflow
(FE_OVERFLOW) or underflow (FE_UNDERFLOW) are raised before inexact
(FE_INEXACT). Whether for overflow or underflow the inexact exception
is also raised is also implementation dependent. The function returns
zero in case the operation was successful, a non-zero value otherwise. */
int
feraiseexcept (int excepts)
{
fenv_t fenv;
if (excepts & ~FE_ALL_EXCEPT)
return EINVAL;
/* Need to save/restore whole environment to modify status word. */
__asm__ volatile ("fnstenv %0" : "=m" (fenv) : );
/* Set desired exception bits. */
fenv._fpu._fpu_sw |= excepts;
/* Set back into FPU state. */
__asm__ volatile ("fldenv %0" :: "m" (fenv));
/* And trigger them - whichever are unmasked. */
__asm__ volatile ("fwait");
return 0;
}
/* Test whether the exception flags indicated by the parameter except
are currently set. If any of them are, a nonzero value is returned
which specifies which exceptions are set. Otherwise the result is zero. */
int
fetestexcept (int excepts)
{
unsigned short sw;
unsigned int mxcsr = 0;
if (excepts & ~FE_ALL_EXCEPT)
return EINVAL;
/* Get status registers. */
__asm__ volatile ("fnstsw %0" : "=m" (sw) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (mxcsr) : );
/* Mask undesired bits out and return result. */
return (sw | mxcsr) & excepts;
}
/* This function stores in the variable pointed to by flagp an
implementation-defined value representing the current setting of the
exception flags indicated by excepts. The function returns zero in
case the operation was successful, a non-zero value otherwise. */
int
fegetexceptflag (fexcept_t *flagp, int excepts)
{
unsigned short sw;
unsigned int mxcsr = 0;
if (excepts & ~FE_ALL_EXCEPT)
return EINVAL;
/* Get status registers. */
__asm__ volatile ("fnstsw %0" : "=m" (sw) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (mxcsr) : );
/* Mask undesired bits out and set result. */
*flagp = (sw | mxcsr) & excepts;
return 0;
}
/* This function restores the flags for the exceptions indicated by
excepts to the values stored in the variable pointed to by flagp. */
int
fesetexceptflag (const fexcept_t *flagp, int excepts)
{
fenv_t fenv;
if (excepts & ~FE_ALL_EXCEPT)
return EINVAL;
/* Need to save/restore whole environment to modify status word. */
fegetenv (&fenv);
/* Set/Clear desired exception bits. */
fenv._fpu._fpu_sw &= ~excepts;
fenv._fpu._fpu_sw |= excepts & *flagp;
fenv._sse_mxcsr &= ~excepts;
fenv._sse_mxcsr |= excepts & *flagp;
/* Set back into FPU state. */
return fesetenv (&fenv);
}
/* Returns the currently selected rounding mode, represented by one of the
values of the defined rounding mode macros. */
int
fegetround (void)
{
unsigned short cw;
/* Get control word. We assume SSE and x87 stay in sync. */
__asm__ volatile ("fnstcw %0" : "=m" (cw) : );
return (cw & FE_CW_ROUND_MASK) >> FE_CW_ROUND_SHIFT;
}
/* Changes the currently selected rounding mode to round. If round does
not correspond to one of the supported rounding modes nothing is changed.
fesetround returns zero if it changed the rounding mode, a nonzero value
if the mode is not supported. */
int
fesetround (int round)
{
unsigned short cw;
unsigned int mxcsr = 0;
/* Will succeed for any valid value of the input parameter. */
if (round < FE_TONEAREST || round > FE_TOWARDZERO)
return EINVAL;
/* Get control words. */
__asm__ volatile ("fnstcw %0" : "=m" (cw) : );
if (use_sse)
__asm__ volatile ("stmxcsr %0" : "=m" (mxcsr) : );
/* Twiddle bits. */
cw &= ~FE_CW_ROUND_MASK;
cw |= (round << FE_CW_ROUND_SHIFT);
mxcsr &= ~FE_MXCSR_ROUND_MASK;
mxcsr |= (round << FE_MXCSR_ROUND_SHIFT);
/* Set back into FPU state. */
__asm__ volatile ("fldcw %0" :: "m" (cw));
if (use_sse)
__asm__ volatile ("ldmxcsr %0" :: "m" (mxcsr));
/* Indicate success. */
return 0;
}
/* Returns the currently selected precision, represented by one of the
values of the defined precision macros. */
int
fegetprec (void)
{
unsigned short cw;
/* Get control word. */
__asm__ volatile ("fnstcw %0" : "=m" (cw) : );
return (cw & FE_CW_PREC_MASK) >> FE_CW_PREC_SHIFT;
}
/* http://www.open-std.org/jtc1/sc22//WG14/www/docs/n752.htm:
The fesetprec function establishes the precision represented by its
argument prec. If the argument does not match a precision macro, the
precision is not changed.
The fesetprec function returns a nonzero value if and only if the
argument matches a precision macro (that is, if and only if the requested
precision can be established). */
int
fesetprec (int prec)
{
unsigned short cw;
/* Will succeed for any valid value of the input parameter. */
switch (prec)
{
case FE_FLTPREC:
case FE_DBLPREC:
case FE_LDBLPREC:
break;
default:
return 0;
}
/* Get control word. */
__asm__ volatile ("fnstcw %0" : "=m" (cw) : );
/* Twiddle bits. */
cw &= ~FE_CW_PREC_MASK;
cw |= (prec << FE_CW_PREC_SHIFT);
/* Set back into FPU state. */
__asm__ volatile ("fldcw %0" :: "m" (cw));
/* Indicate success. */
return 1;
}
/* Set up the FPU and SSE environment at the start of execution. */
void
_feinitialise (void)
{
unsigned int edx, eax;
extern fenv_t __fe_dfl_env;
/* Check for presence of SSE: invoke CPUID #1, check EDX bit 25. */
eax = 1;
__asm__ volatile ("cpuid" : "=d" (edx), "+a" (eax) :: "%ecx", "%ebx");
/* If this flag isn't set we'll avoid trying to execute any SSE. */
if ((edx & (1 << 25)) != 0)
use_sse = true;
/* Reset FPU: extended prec, all exceptions cleared and masked off. */
__asm__ volatile ("fninit");
/* The default cw value, 0x37f, is rounding mode zero. The MXCSR has
no precision control, so the only thing to do is set the exception
mask bits. */
/* initialize the MXCSR register: mask all exceptions */
unsigned int mxcsr = __FE_ALL_EXCEPT_X86 << FE_SSE_EXCEPT_MASK_SHIFT;
if (use_sse)
__asm__ volatile ("ldmxcsr %0" :: "m" (mxcsr));
/* Setup unmasked environment, but leave __FE_DENORM masked. */
feenableexcept (FE_ALL_EXCEPT);
fegetenv (&fe_nomask_env);
/* Restore default exception masking (all masked). */
fedisableexcept (FE_ALL_EXCEPT);
/* Finally cache state as default environment. */
fegetenv (&__fe_dfl_env);
}