/* { dg-options "--std=gnu99" } */ /* Check that optimizations like (x * 1) to x, or (x * -1) to -x, do not apply to decimal float computations where trailing zeroes are significant. */ extern void abort (void); int failcnt; #ifdef DBG extern int printf (const char *, ...); #define FAILURE { printf ("failed at line %d\n", __LINE__); failcnt++; } #else #define FAILURE abort (); #endif #define COMPARE32(A,B) \ A.i == B.i #define COMPARE64(A,B) \ A.i[0] == B.i[0] && A.i[1] == B.i[1] #define COMPARE128(A,B) \ A.i[0] == B.i[0] && A.i[1] == B.i[1] && A.i[2] == B.i[2] && A.i[3] == B.i[3] typedef union { _Decimal32 d; unsigned int i; } u32; typedef union { _Decimal64 d; unsigned int i[2]; } u64; typedef union { _Decimal128 d; unsigned int i[4]; } u128; volatile u32 p32_1; volatile u32 p32_1_0; volatile u32 p32_2_0; volatile u32 m32_1; volatile u32 m32_1_0; volatile u32 m32_2_0; volatile u32 a32; volatile u64 p64_1; volatile u64 p64_1_0; volatile u64 p64_2_0; volatile u64 m64_1; volatile u64 m64_1_0; volatile u64 m64_2_0; volatile u64 a64; volatile u128 p128_1; volatile u128 p128_1_0; volatile u128 p128_2_0; volatile u128 m128_1; volatile u128 m128_1_0; volatile u128 m128_2_0; volatile u128 a128; void init32 (void) { p32_1.d = 1.DF; p32_1_0.d = 1.0DF; p32_2_0.d = 2.0DF; m32_1.d = -1.DF; m32_1_0.d = -1.0DF; m32_2_0.d = -2.0DF; } void init64 (void) { p64_1.d = 1.DD; p64_1_0.d = 1.0DD; p64_2_0.d = 2.0DD; m64_1.d = -1.DD; m64_1_0.d = -1.0DD; m64_2_0.d = -2.0DD; } void init128 (void) { p128_1.d = 1.DL; p128_1_0.d = 1.0DL; p128_2_0.d = 2.0DL; m128_1.d = -1.DL; m128_1_0.d = -1.0DL; m128_2_0.d = -2.0DL; } void doit32 (void) { /* Multiplying by a value with no trailing zero should not change the quantum exponent. */ a32.d = p32_2_0.d * p32_1.d; if (! (COMPARE32 (a32, p32_2_0))) FAILURE a32.d = p32_2_0.d * 1.DF; if (! (COMPARE32 (a32, p32_2_0))) FAILURE a32.d = p32_2_0.d * m32_1.d; if (! (COMPARE32 (a32, m32_2_0))) FAILURE a32.d = p32_2_0.d * -1.DF; if (! (COMPARE32 (a32, m32_2_0))) FAILURE /* Multiplying by a value with a trailing zero should change the quantum exponent. */ a32.d = p32_2_0.d * p32_1_0.d; if (COMPARE32 (a32, p32_2_0)) FAILURE a32.d = p32_2_0.d * 1.0DF; if (COMPARE32 (a32, p32_2_0)) FAILURE a32.d = p32_2_0.d * m32_1_0.d; if (COMPARE32 (a32, m32_2_0)) FAILURE a32.d = p32_2_0.d * -1.0DF; if (COMPARE32 (a32, m32_2_0)) FAILURE } void doit64 (void) { /* Multiplying by a value with no trailing zero should not change the quantum exponent. */ a64.d = p64_2_0.d * p64_1.d; if (! (COMPARE64 (a64, p64_2_0))) FAILURE a64.d = p64_2_0.d * 1.DD; if (! (COMPARE64 (a64, p64_2_0))) FAILURE a64.d = p64_2_0.d * m64_1.d; if (! (COMPARE64 (a64, m64_2_0))) FAILURE a64.d = p64_2_0.d * -1.DD; if (! (COMPARE64 (a64, m64_2_0))) FAILURE /* Multiplying by a value with a trailing zero should change the quantum exponent. */ a64.d = p64_2_0.d * p64_1_0.d; if (COMPARE64 (a64, p64_2_0)) FAILURE a64.d = p64_2_0.d * 1.0DD; if (COMPARE64 (a64, p64_2_0)) FAILURE a64.d = p64_2_0.d * m64_1_0.d; if (COMPARE64 (a64, m64_2_0)) FAILURE a64.d = p64_2_0.d * -1.0DD; if (COMPARE64 (a64, m64_2_0)) FAILURE } void doit128 (void) { /* Multiplying by a value with no trailing zero should not change the quantum exponent. */ a128.d = p128_2_0.d * p128_1_0.d; if (COMPARE128 (a128, p128_2_0)) FAILURE a128.d = p128_2_0.d * 1.0DL; if (COMPARE128 (a128, p128_2_0)) FAILURE a128.d = p128_2_0.d * m128_1_0.d; if (COMPARE128 (a128, m128_2_0)) FAILURE a128.d = p128_2_0.d * -1.0DL; if (COMPARE128 (a128, m128_2_0)) FAILURE /* Multiplying by a value with a trailing zero should change the quantum exponent. */ a128.d = p128_2_0.d * p128_1.d; if (! (COMPARE128 (a128, p128_2_0))) FAILURE a128.d = p128_2_0.d * 1.DL; if (! (COMPARE128 (a128, p128_2_0))) FAILURE a128.d = p128_2_0.d * m128_1.d; if (! (COMPARE128 (a128, m128_2_0))) FAILURE a128.d = p128_2_0.d * -1.DL; if (! (COMPARE128 (a128, m128_2_0))) FAILURE } int main (void) { init32 (); init64 (); init128 (); doit32 (); doit64 (); doit128 (); if (failcnt != 0) abort (); return 0; }