// RUN: %clang %s -emit-llvm %O0opt -g -c -o %t1.bc // RUN: rm -rf %t.klee-out // NOTE: Have to pass `--optimize=false` to avoid vector operations being // constant folded away. // RUN: %klee --output-dir=%t.klee-out --optimize=false --exit-on-error %t1.bc #include #include #include typedef uint32_t v4ui __attribute__((vector_size(16))); typedef int32_t v4si __attribute__((vector_size(16))); #define ASSERT_EL(C, OP, A, B, INDEX) assert(C[INDEX] == (A[INDEX] OP B[INDEX])) #define ASSERT_ELV4(C, OP, A, B) \ do { \ ASSERT_EL(C, OP, A, B, 0); \ ASSERT_EL(C, OP, A, B, 1); \ ASSERT_EL(C, OP, A, B, 2); \ ASSERT_EL(C, OP, A, B, 3); \ } while (0); #define ASSERT_EL_TRUTH(C, OP, A, B, INDEX) \ assert(C[INDEX] ? (A[INDEX] OP B[INDEX]) : (!(A[INDEX] OP B[INDEX]))) #define ASSERT_EL_TRUTH_V4(C, OP, A, B) \ do { \ ASSERT_EL_TRUTH(C, OP, A, B, 0); \ ASSERT_EL_TRUTH(C, OP, A, B, 1); \ ASSERT_EL_TRUTH(C, OP, A, B, 2); \ ASSERT_EL_TRUTH(C, OP, A, B, 3); \ } while (0); #define ASSERT_EL_TERNARY_SCALAR_CONDITION(C, CONDITION, A, B, INDEX) \ assert(C[INDEX] == (CONDITION ? A[INDEX] : B[INDEX])) #define ASSERT_EL_TERNARY_SCALAR_CONDITION_V4(C, CONDITION, A, B) \ do { \ ASSERT_EL_TERNARY_SCALAR_CONDITION(C, CONDITION, A, B, 0); \ ASSERT_EL_TERNARY_SCALAR_CONDITION(C, CONDITION, A, B, 1); \ ASSERT_EL_TERNARY_SCALAR_CONDITION(C, CONDITION, A, B, 2); \ ASSERT_EL_TERNARY_SCALAR_CONDITION(C, CONDITION, A, B, 3); \ } while (0); int main() { // Unsigned tests { v4ui a = {0, 1, 2, 3}; v4ui b = {10, 20, 30, 3}; // Test addition v4ui c = a + b; ASSERT_ELV4(c, +, a, b); // Test subtraction c = b - a; ASSERT_ELV4(c, -, b, a); // Test multiplication c = a * b; ASSERT_ELV4(c, *, a, b); // Test division c = a / b; ASSERT_ELV4(c, /, a, b); // Test mod c = a % b; ASSERT_ELV4(c, %, a, b); // Test bitwise and c = a & b; ASSERT_ELV4(c, &, a, b); // Test bitwise or c = a | b; ASSERT_ELV4(c, |, a, b); // Test bitwise xor c = a ^ b; ASSERT_ELV4(c, ^, a, b); // Test left shift c = b << a; ASSERT_ELV4(c, <<, b, a); // Test logic right shift c = b >> a; ASSERT_ELV4(c, >>, b, a); // NOTE: Can't use `ASSERT_ELV4` due to semantics // of GCC vector extensions. See // https://gcc.gnu.org/onlinedocs/gcc/Vector-Extensions.html // Test == c = a == b; ASSERT_EL_TRUTH_V4(c, ==, a, b); // Test < c = a < b; ASSERT_EL_TRUTH_V4(c, <, a, b); // Test <= c = a <= b; ASSERT_EL_TRUTH_V4(c, <=, a, b); // Test > c = a > b; ASSERT_EL_TRUTH_V4(c, >, a, b); // Test >= c = a > b; ASSERT_EL_TRUTH_V4(c, >, a, b); // Test != c = a != b; ASSERT_EL_TRUTH_V4(c, !=, a, b); // Test ternary operator c = 0 ? a : b; ASSERT_EL_TERNARY_SCALAR_CONDITION_V4(c, 0, a, b); c = 1 ? a : b; ASSERT_EL_TERNARY_SCALAR_CONDITION_V4(c, 1, a, b); } // Signed tests { v4si a = {-1, 2, -3, 4}; v4si b = {-10, 20, -30, 40}; // Test addition v4si c = a + b; ASSERT_ELV4(c, +, a, b); // Test subtraction c = b - a; ASSERT_ELV4(c, -, b, a); // Test multiplication c = a * b; ASSERT_ELV4(c, *, a, b); // Test division c = a / b; ASSERT_ELV4(c, /, a, b); // Test mod c = a % b; ASSERT_ELV4(c, %, a, b); // Test bitwise and c = a & b; ASSERT_ELV4(c, &, a, b); // Test bitwise or c = a | b; ASSERT_ELV4(c, |, a, b); // Test bitwise xor c = a ^ b; ASSERT_ELV4(c, ^, a, b); // Test left shift v4si shifts = {1, 2, 3, 4}; c = b << shifts; ASSERT_ELV4(c, <<, b, shifts); // Test arithmetic right shift c = b >> shifts; ASSERT_ELV4(c, >>, b, shifts); // Test == c = a == b; ASSERT_EL_TRUTH_V4(c, ==, a, b); // Test < c = a < b; ASSERT_EL_TRUTH_V4(c, <, a, b); // Test <= c = a <= b; ASSERT_EL_TRUTH_V4(c, <=, a, b); // Test > c = a > b; ASSERT_EL_TRUTH_V4(c, >, a, b); // Test >= c = a > b; ASSERT_EL_TRUTH_V4(c, >, a, b); // Test != c = a != b; ASSERT_EL_TRUTH_V4(c, !=, a, b); // Test ternary operator c = 0 ? a : b; ASSERT_EL_TERNARY_SCALAR_CONDITION_V4(c, 0, a, b); c = 1 ? a : b; ASSERT_EL_TERNARY_SCALAR_CONDITION_V4(c, 1, a, b); } return 0; }