/*- * Copyright (c) 2004-2005 David Schultz * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD: src/lib/msun/i387/fenv.c,v 1.2 2005/03/17 22:21:46 das Exp $ */ #include #include #include "fenv.h" #define ROUND_MASK (FE_TONEAREST | FE_DOWNWARD | FE_UPWARD | FE_TOWARDZERO) /* * The hardware default control word for i387's and later coprocessors is * 0x37F, giving: * * round to nearest * 64-bit precision * all exceptions masked. * * We modify the affine mode bit and precision bits in this to give: * * affine mode for 287's (if they work at all) (1 in bitfield 1<<12) * 53-bit precision (2 in bitfield 3<<8) * * 64-bit precision often gives bad results with high level languages * because it makes the results of calculations depend on whether * intermediate values are stored in memory or in FPU registers. */ #define __INITIAL_NPXCW__ 0x127F #define __INITIAL_MXCSR__ 0x1F80 /* * As compared to the x87 control word, the SSE unit's control word * has the rounding control bits offset by 3 and the exception mask * bits offset by 7. */ #define _SSE_ROUND_SHIFT 3 #define _SSE_EMASK_SHIFT 7 const fenv_t __fe_dfl_env = { __INITIAL_NPXCW__, /*__control*/ 0x0000, /*__mxcsr_hi*/ 0x0000, /*__status*/ 0x1f80, /*__mxcsr_lo*/ 0xffffffff, /*__tag*/ { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xff, 0xff } /*__other*/ }; #define __fldcw(__cw) __asm __volatile("fldcw %0" : : "m" (__cw)) #define __fldenv(__env) __asm __volatile("fldenv %0" : : "m" (__env)) #define __fldenvx(__env) __asm __volatile("fldenv %0" : : "m" (__env) \ : "st", "st(1)", "st(2)", "st(3)", "st(4)", \ "st(5)", "st(6)", "st(7)") #define __fnclex() __asm __volatile("fnclex") #define __fnstenv(__env) __asm __volatile("fnstenv %0" : "=m" (*(__env))) #define __fnstcw(__cw) __asm __volatile("fnstcw %0" : "=m" (*(__cw))) #define __fnstsw(__sw) __asm __volatile("fnstsw %0" : "=am" (*(__sw))) #define __fwait() __asm __volatile("fwait") #define __ldmxcsr(__csr) __asm __volatile("ldmxcsr %0" : : "m" (__csr)) #define __stmxcsr(__csr) __asm __volatile("stmxcsr %0" : "=m" (*(__csr))) /* After testing for SSE support once, we cache the result in __has_sse. */ enum __sse_support { __SSE_YES, __SSE_NO, __SSE_UNK }; #ifdef __SSE__ #define __HAS_SSE() 1 #else #define __HAS_SSE() (__has_sse == __SSE_YES || \ (__has_sse == __SSE_UNK && __test_sse())) #endif enum __sse_support __has_sse = #ifdef __SSE__ __SSE_YES; #else __SSE_UNK; #endif #ifndef __SSE__ #define getfl(x) __asm __volatile("pushfl\n\tpopl %0" : "=mr" (*(x))) #define setfl(x) __asm __volatile("pushl %0\n\tpopfl" : : "g" (x)) #define cpuid_dx(x) __asm __volatile("pushl %%ebx\n\tmovl $1, %%eax\n\t" \ "cpuid\n\tpopl %%ebx" \ : "=d" (*(x)) : : "eax", "ecx") /* * Test for SSE support on this processor. We need to do this because * we need to use ldmxcsr/stmxcsr to get correct results if any part * of the program was compiled to use SSE floating-point, but we can't * use SSE on older processors. */ int __test_sse(void) { int flag, nflag; int dx_features; /* Am I a 486? */ getfl(&flag); nflag = flag ^ 0x200000; setfl(nflag); getfl(&nflag); if (flag != nflag) { /* Not a 486, so CPUID should work. */ cpuid_dx(&dx_features); if (dx_features & 0x2000000) { __has_sse = __SSE_YES; return (1); } } __has_sse = __SSE_NO; return (0); } #endif /* __SSE__ */ int fesetexceptflag(const fexcept_t *flagp, int excepts) { fenv_t env; __uint32_t mxcsr; excepts &= FE_ALL_EXCEPT; if (excepts) { /* Do nothing if excepts is 0 */ __fnstenv(&env); env.__status &= ~excepts; env.__status |= *flagp & excepts; __fnclex(); __fldenv(env); if (__HAS_SSE()) { __stmxcsr(&mxcsr); mxcsr &= ~excepts; mxcsr |= *flagp & excepts; __ldmxcsr(mxcsr); } } return (0); } int feraiseexcept(int excepts) { fexcept_t ex = excepts; fesetexceptflag(&ex, excepts); __fwait(); return (0); } int fegetenv(fenv_t *envp) { __uint32_t mxcsr; __fnstenv(envp); /* * fnstenv masks all exceptions, so we need to restore * the old control word to avoid this side effect. */ __fldcw(envp->__control); if (__HAS_SSE()) { __stmxcsr(&mxcsr); envp->__mxcsr_hi = mxcsr >> 16; envp->__mxcsr_lo = mxcsr & 0xffff; } return (0); } int feholdexcept(fenv_t *envp) { __uint32_t mxcsr; fenv_t env; __fnstenv(&env); *envp = env; env.__status &= ~FE_ALL_EXCEPT; env.__control |= FE_ALL_EXCEPT; __fnclex(); __fldenv(env); if (__HAS_SSE()) { __stmxcsr(&mxcsr); envp->__mxcsr_hi = mxcsr >> 16; envp->__mxcsr_lo = mxcsr & 0xffff; mxcsr &= ~FE_ALL_EXCEPT; mxcsr |= FE_ALL_EXCEPT << _SSE_EMASK_SHIFT; __ldmxcsr(mxcsr); } return (0); } int feupdateenv(const fenv_t *envp) { __uint32_t mxcsr; __uint16_t status; __fnstsw(&status); if (__HAS_SSE()) { __stmxcsr(&mxcsr); } else { mxcsr = 0; } fesetenv(envp); feraiseexcept((mxcsr | status) & FE_ALL_EXCEPT); return (0); } int feenableexcept(int mask) { __uint32_t mxcsr; __uint16_t control, omask; mask &= FE_ALL_EXCEPT; __fnstcw(&control); if (__HAS_SSE()) { __stmxcsr(&mxcsr); } else { mxcsr = 0; } omask = ~(control | mxcsr >> _SSE_EMASK_SHIFT) & FE_ALL_EXCEPT; if (mask) { control &= ~mask; __fldcw(control); if (__HAS_SSE()) { mxcsr &= ~(mask << _SSE_EMASK_SHIFT); __ldmxcsr(mxcsr); } } return (omask); } int fedisableexcept(int mask) { __uint32_t mxcsr; __uint16_t control, omask; mask &= FE_ALL_EXCEPT; __fnstcw(&control); if (__HAS_SSE()) { __stmxcsr(&mxcsr); } else { mxcsr = 0; } omask = ~(control | mxcsr >> _SSE_EMASK_SHIFT) & FE_ALL_EXCEPT; if (mask) { control |= mask; __fldcw(control); if (__HAS_SSE()) { mxcsr |= mask << _SSE_EMASK_SHIFT; __ldmxcsr(mxcsr); } } return (omask); } int feclearexcept(int excepts) { fenv_t env; __uint32_t mxcsr; excepts &= FE_ALL_EXCEPT; if (excepts) { /* Do nothing if excepts is 0 */ __fnstenv(&env); env.__status &= ~excepts; __fnclex(); __fldenv(env); if (__HAS_SSE()) { __stmxcsr(&mxcsr); mxcsr &= ~excepts; __ldmxcsr(mxcsr); } } return (0); } int fegetexceptflag(fexcept_t *flagp, int excepts) { __uint32_t mxcsr; __uint16_t status; excepts &= FE_ALL_EXCEPT; __fnstsw(&status); if (__HAS_SSE()) { __stmxcsr(&mxcsr); } else { mxcsr = 0; } *flagp = (status | mxcsr) & excepts; return (0); } int fetestexcept(int excepts) { __uint32_t mxcsr; __uint16_t status; excepts &= FE_ALL_EXCEPT; if (excepts) { /* Do nothing if excepts is 0 */ __fnstsw(&status); if (__HAS_SSE()) { __stmxcsr(&mxcsr); } else { mxcsr = 0; } return ((status | mxcsr) & excepts); } return (0); } int fegetround(void) { __uint16_t control; /* * We assume that the x87 and the SSE unit agree on the * rounding mode. Reading the control word on the x87 turns * out to be about 5 times faster than reading it on the SSE * unit on an Opteron 244. */ __fnstcw(&control); return (control & ROUND_MASK); } int fesetround(int round) { __uint32_t mxcsr; __uint16_t control; if (round & ~ROUND_MASK) { return (-1); } else { __fnstcw(&control); control &= ~ROUND_MASK; control |= round; __fldcw(control); if (__HAS_SSE()) { __stmxcsr(&mxcsr); mxcsr &= ~(ROUND_MASK << _SSE_ROUND_SHIFT); mxcsr |= round << _SSE_ROUND_SHIFT; __ldmxcsr(mxcsr); } return (0); } } int fesetenv(const fenv_t *envp) { fenv_t env = *envp; __uint32_t mxcsr; mxcsr = (env.__mxcsr_hi << 16) | (env.__mxcsr_lo); env.__mxcsr_hi = 0xffff; env.__mxcsr_lo = 0xffff; /* * XXX Using fldenvx() instead of fldenv() tells the compiler that this * instruction clobbers the i387 register stack. This happens because * we restore the tag word from the saved environment. Normally, this * would happen anyway and we wouldn't care, because the ABI allows * function calls to clobber the i387 regs. However, fesetenv() is * inlined, so we need to be more careful. */ __fldenvx(env); if (__HAS_SSE()) { __ldmxcsr(mxcsr); } return (0); } int fegetexcept(void) { __uint16_t control; /* * We assume that the masks for the x87 and the SSE unit are * the same. */ __fnstcw(&control); return (~control & FE_ALL_EXCEPT); }