// RUN: %clang_cc1 -triple x86_64-linux -verify=norounding -Wno-unknown-pragmas %s // RUN: %clang_cc1 -triple x86_64-linux -verify=rounding %s -frounding-math -Wno-unknown-pragmas // rounding-no-diagnostics #define fold(x) (__builtin_constant_p(x) ? (x) : (x)) constexpr double a = 1.0 / 3.0; constexpr int f(int n) { return int(n * (1.0 / 3.0)); } using T = int[f(3)]; using T = int[1]; enum Enum { enum_a = f(3) }; struct Bitfield { unsigned int n : 1; unsigned int m : f(3); }; void f(Bitfield &b) { b.n = int(6 * (1.0 / 3.0)); // norounding-warning {{changes value from 2 to 0}} } const int k = 3 * (1.0 / 3.0); static_assert(k == 1, ""); void g() { // FIXME: Constant-evaluating this initializer is surprising, and violates // the recommended practice in C++ [expr.const]p12: // // Implementations should provide consistent results of floating-point // evaluations, irrespective of whether the evaluation is performed during // translation or during program execution. const int k = 3 * (1.0 / 3.0); static_assert(k == 1, ""); } int *h() { return new int[int(-3 * (1.0 / 3.0))]; // norounding-error {{too large}} } // nextUp(1.F) == 0x1.000002p0F static_assert(1.0F + 0x0.000001p0F == 0x1.0p0F, ""); char Arr01[1 + (1.0F + 0x0.000001p0F > 1.0F)]; static_assert(sizeof(Arr01) == 1, ""); struct S1 { int : (1.0F + 0x0.000001p0F > 1.0F); int f; }; static_assert(sizeof(S1) == sizeof(int), ""); #pragma STDC FENV_ROUND FE_UPWARD static_assert(1.0F + 0x0.000001p0F == 0x1.000002p0F, ""); char Arr01u[1 + (1.0F + 0x0.000001p0F > 1.0F)]; static_assert(sizeof(Arr01u) == 2, ""); struct S1u { int : (1.0F + 0x0.000001p0F > 1.0F); int f; }; static_assert(sizeof(S1u) > sizeof(int), ""); #pragma STDC FENV_ROUND FE_DOWNWARD static_assert(1.0F + 0x0.000001p0F == 1.0F, ""); char Arr01d[1 + (1.0F + 0x0.000001p0F > 1.0F)]; static_assert(sizeof(Arr01d) == 1, ""); struct S1d { int : (1.0F + 0x0.000001p0F > 1.0F); int f; }; static_assert(sizeof(S1d) == sizeof(int), "");