| /external/compiler-rt/lib/ |
| umodsi3.c | 19 su_int COMPILER_RT_ABI __udivsi3(su_int a, su_int b);
21 COMPILER_RT_ABI su_int
22 __umodsi3(su_int a, su_int b)
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| udivmodsi4.c | 17 extern su_int COMPILER_RT_ABI __udivsi3(su_int n, su_int d);
22 COMPILER_RT_ABI su_int
23 __udivmodsi4(su_int a, su_int b, su_int* rem)
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| paritysi2.c | 22 su_int x = (su_int)a;
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| divsi3.c | 17 su_int COMPILER_RT_ABI __udivsi3(su_int n, su_int d);
34 * this calls __udivsi3 (notice the cast to su_int).
38 return ((su_int)a/(su_int)b ^ s_a) - s_a; /* negate if s_a == -1 */
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| udivsi3.c | 24 COMPILER_RT_ABI su_int
25 __udivsi3(su_int n, su_int d)
27 const unsigned n_uword_bits = sizeof(su_int) * CHAR_BIT;
28 su_int q;
29 su_int r;
47 su_int carry = 0;
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| fixunssfsi.c | 22 * su_int is a 32 bit integral type
23 * value in float is representable in su_int or is negative
31 COMPILER_RT_ABI su_int
39 su_int r = (fb.u & 0x007FFFFF) | 0x00800000;
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| int_types.h | 24 typedef unsigned su_int; typedef
35 su_int low;
39 su_int low;
50 su_int low;
51 su_int high;
53 su_int high;
54 su_int low;
112 su_int u;
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| popcountsi2.c | 22 su_int x = (su_int)a;
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| clzsi2.c | 24 su_int x = (su_int)a;
27 su_int r = t; /* r = [0, 16] */
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| ctzsi2.c | 24 su_int x = (su_int)a;
27 su_int r = t; /* r = [0, 16] */
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| modsi3.c | 17 su_int COMPILER_RT_ABI __divsi3(si_int a, si_int b);
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| popcountdi2.c | 29 su_int x = (su_int)(x2 + (x2 >> 32));
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| floattidf.c | 78 fb.u.s.high = ((su_int)s & 0x80000000) | /* sign */
80 ((su_int)(a >> 32) & 0x000FFFFF); /* mantissa-high */
81 fb.u.s.low = (su_int)a; /* mantissa-low */
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| popcountti2.c | 36 su_int x = (su_int)(x2 + (x2 >> 32));
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| fixunsxfsi.c | 24 * su_int is a 32 bit integral type
25 * value in long double is representable in su_int or is negative
33 su_int
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| muldi3.c | 21 __muldsi3(su_int a, su_int b)
25 const su_int lower_mask = (su_int)~0 >> bits_in_word_2;
27 su_int t = r.s.low >> bits_in_word_2;
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| floatdisf.c | 76 fb.u = ((su_int)s & 0x80000000) | /* sign */
78 ((su_int)a & 0x007FFFFF); /* mantissa */
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| floattisf.c | 78 fb.u = ((su_int)s & 0x80000000) | /* sign */
80 ((su_int)a & 0x007FFFFF); /* mantissa */
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| floatuntidf.c | 77 ((su_int)(a >> 32) & 0x000FFFFF); /* mantissa-high */
78 fb.u.s.low = (su_int)a; /* mantissa-low */
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| fixunsdfsi.c | 22 * su_int is a 32 bit integral type
23 * value in double is representable in su_int or is negative
31 COMPILER_RT_ABI su_int
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| floatdixf.c | 40 fb.u.high.s.low = ((su_int)s & 0x00008000) | /* sign */
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| /external/compiler-rt/test/Unit/ |
| udivmodsi4_test.c | 19 extern su_int __udivmodsi4(su_int a, su_int b, su_int* rem);
21 int test__udivmodsi4(su_int a, su_int b,
22 su_int expected_result, su_int expected_rem)
24 su_int rem;
25 su_int result = __udivmodsi4(a, b, &rem)
[all...] |
| fixunsdfsi_test.c | 21 // su_int is a 32 bit integral type
22 // value in double is representable in su_int or is negative
27 su_int __fixunsdfsi(double a);
29 int test__fixunsdfsi(double a, su_int expected)
31 su_int x = __fixunsdfsi(a);
37 char assumption_2[sizeof(su_int)*CHAR_BIT == 32] = {0};
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| fixunsxfsi_test.c | 22 // su_int is a 32 bit integral type
23 // value in long double is representable in su_int or is negative
29 su_int __fixunsxfsi(long double a);
31 int test__fixunsxfsi(long double a, su_int expected)
33 su_int x = __fixunsxfsi(a);
39 char assumption_2[sizeof(su_int)*CHAR_BIT == 32] = {0};
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| fixunssfsi_test.c | 21 // su_int is a 32 bit integral type
22 // value in float is representable in su_int or is negative
27 su_int __fixunssfsi(float a);
29 int test__fixunssfsi(float a, su_int expected)
31 su_int x = __fixunssfsi(a);
37 char assumption_2[sizeof(su_int)*CHAR_BIT == 32] = {0};
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