/*- * Copyright (c) 2012 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. */ /* * Test that floating-point arithmetic works as specified by the C standard. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #ifdef __i386__ #include #endif #define ALL_STD_EXCEPT (FE_DIVBYZERO | FE_INEXACT | FE_INVALID | \ FE_OVERFLOW | FE_UNDERFLOW) #define TWICE(x) ((x) + (x)) #define test(desc, pass) test1((desc), (pass), 0) #define skiptest(desc, pass) test1((desc), (pass), 1) #pragma STDC FENV_ACCESS ON static const float one_f = 1.0 + FLT_EPSILON / 2; static const double one_d = 1.0 + DBL_EPSILON / 2; static const long double one_ld = 1.0L + LDBL_EPSILON / 2; static int testnum, failures; static void test1(const char *testdesc, int pass, int skip) { testnum++; printf("%sok %d - %s%s\n", pass || skip ? "" : "not ", testnum, skip ? "(SKIPPED) " : "", testdesc); if (!pass && !skip) failures++; } /* * Compare d1 and d2 using special rules: NaN == NaN and +0 != -0. */ static int fpequal(long double d1, long double d2) { if (d1 != d2) return (isnan(d1) && isnan(d2)); return (copysignl(1.0, d1) == copysignl(1.0, d2)); } void run_zero_opt_test(double d1, double d2) { test("optimizations don't break the sign of 0", fpequal(d1 - d2, 0.0) && fpequal(-d1 + 0.0, 0.0) && fpequal(-d1 - d2, -0.0) && fpequal(-(d1 - d2), -0.0) && fpequal(-d1 - (-d2), 0.0)); } void run_inf_opt_test(double d) { test("optimizations don't break infinities", fpequal(d / d, NAN) && fpequal(0.0 * d, NAN)); } static inline double todouble(long double ld) { return (ld); } static inline float tofloat(double d) { return (d); } void run_tests(void) { volatile long double vld; long double ld; volatile double vd; double d; volatile float vf; float f; int x; test("sign bits", fpequal(-0.0, -0.0) && !fpequal(0.0, -0.0)); vd = NAN; test("NaN equality", fpequal(NAN, NAN) && NAN != NAN && vd != vd); feclearexcept(ALL_STD_EXCEPT); test("NaN comparison returns false", !(vd <= vd)); /* * XXX disabled; gcc/amd64 botches this IEEE 754 requirement by * emitting ucomisd instead of comisd. */ skiptest("FENV_ACCESS: NaN comparison raises invalid exception", fetestexcept(ALL_STD_EXCEPT) == FE_INVALID); vd = 0.0; run_zero_opt_test(vd, vd); vd = INFINITY; run_inf_opt_test(vd); feclearexcept(ALL_STD_EXCEPT); vd = INFINITY; x = (int)vd; /* XXX disabled (works with -O0); gcc doesn't support FENV_ACCESS */ skiptest("FENV_ACCESS: Inf->int conversion raises invalid exception", fetestexcept(ALL_STD_EXCEPT) == FE_INVALID); /* Raising an inexact exception here is an IEEE-854 requirement. */ feclearexcept(ALL_STD_EXCEPT); vd = 0.75; x = (int)vd; test("0.75->int conversion rounds toward 0, raises inexact exception", x == 0 && fetestexcept(ALL_STD_EXCEPT) == FE_INEXACT); feclearexcept(ALL_STD_EXCEPT); vd = -42.0; x = (int)vd; test("-42.0->int conversion is exact, raises no exception", x == -42 && fetestexcept(ALL_STD_EXCEPT) == 0); feclearexcept(ALL_STD_EXCEPT); x = (int)INFINITY; /* XXX disabled; gcc doesn't support FENV_ACCESS */ skiptest("FENV_ACCESS: const Inf->int conversion raises invalid", fetestexcept(ALL_STD_EXCEPT) == FE_INVALID); feclearexcept(ALL_STD_EXCEPT); x = (int)0.5; /* XXX disabled; gcc doesn't support FENV_ACCESS */ skiptest("FENV_ACCESS: const double->int conversion raises inexact", x == 0 && fetestexcept(ALL_STD_EXCEPT) == FE_INEXACT); test("compile-time constants don't have too much precision", one_f == 1.0L && one_d == 1.0L && one_ld == 1.0L); test("const minimum rounding precision", 1.0F + FLT_EPSILON != 1.0F && 1.0 + DBL_EPSILON != 1.0 && 1.0L + LDBL_EPSILON != 1.0L); /* It isn't the compiler's fault if this fails on FreeBSD/i386. */ vf = FLT_EPSILON; vd = DBL_EPSILON; vld = LDBL_EPSILON; test("runtime minimum rounding precision", 1.0F + vf != 1.0F && 1.0 + vd != 1.0 && 1.0L + vld != 1.0L); test("explicit float to float conversion discards extra precision", (float)(1.0F + FLT_EPSILON * 0.5F) == 1.0F && (float)(1.0F + vf * 0.5F) == 1.0F); test("explicit double to float conversion discards extra precision", (float)(1.0 + FLT_EPSILON * 0.5) == 1.0F && (float)(1.0 + vf * 0.5) == 1.0F); test("explicit ldouble to float conversion discards extra precision", (float)(1.0L + FLT_EPSILON * 0.5L) == 1.0F && (float)(1.0L + vf * 0.5L) == 1.0F); test("explicit double to double conversion discards extra precision", (double)(1.0 + DBL_EPSILON * 0.5) == 1.0 && (double)(1.0 + vd * 0.5) == 1.0); test("explicit ldouble to double conversion discards extra precision", (double)(1.0L + DBL_EPSILON * 0.5L) == 1.0 && (double)(1.0L + vd * 0.5L) == 1.0); /* * FLT_EVAL_METHOD > 1 implies that float expressions are always * evaluated in double precision or higher, but some compilers get * this wrong when registers spill to memory. The following expression * forces a spill when there are at most 8 FP registers. */ test("implicit promption to double or higher precision is consistent", #if FLT_EVAL_METHOD == 1 || FLT_EVAL_METHOD == 2 || defined(__i386__) TWICE(TWICE(TWICE(TWICE(TWICE( TWICE(TWICE(TWICE(TWICE(1.0F + vf * 0.5F))))))))) == (1.0 + FLT_EPSILON * 0.5) * 512.0 #else 1 #endif ); f = 1.0 + FLT_EPSILON * 0.5; d = 1.0L + DBL_EPSILON * 0.5L; test("const assignment discards extra precision", f == 1.0F && d == 1.0); f = 1.0 + vf * 0.5; d = 1.0L + vd * 0.5L; test("variable assignment discards explicit extra precision", f == 1.0F && d == 1.0); f = 1.0F + vf * 0.5F; d = 1.0 + vd * 0.5; test("variable assignment discards implicit extra precision", f == 1.0F && d == 1.0); test("return discards extra precision", tofloat(1.0 + vf * 0.5) == 1.0F && todouble(1.0L + vd * 0.5L) == 1.0); fesetround(FE_UPWARD); /* XXX disabled (works with -frounding-math) */ skiptest("FENV_ACCESS: constant arithmetic respects rounding mode", 1.0F + FLT_MIN == 1.0F + FLT_EPSILON && 1.0 + DBL_MIN == 1.0 + DBL_EPSILON && 1.0L + LDBL_MIN == 1.0L + LDBL_EPSILON); fesetround(FE_TONEAREST); ld = vld * 0.5; test("associativity is respected", 1.0L + ld + (LDBL_EPSILON * 0.5) == 1.0L && 1.0L + (LDBL_EPSILON * 0.5) + ld == 1.0L && ld + 1.0 + (LDBL_EPSILON * 0.5) == 1.0L && ld + (LDBL_EPSILON * 0.5) + 1.0 == 1.0L + LDBL_EPSILON); } int main(int argc, char *argv[]) { printf("1..26\n"); #ifdef __i386__ fpsetprec(FP_PE); #endif run_tests(); return (failures); }