Improved float XOR readability

master
Xavier Arteaga 4 years ago committed by Xavier Arteaga
parent 751b6858b3
commit eef3fac863

@ -211,10 +211,17 @@ void srsran_sequence_state_init(srsran_sequence_state_t* s, uint32_t seed)
s->x2 = sequence_get_x2_init(seed);
}
#define FLOAT_U32_XOR(DST, SRC, U32_MASK) \
do { \
uint32_t temp_u32; \
memcpy(&temp_u32, &(SRC), 4); \
temp_u32 ^= (U32_MASK); \
memcpy(&(DST), &temp_u32, 4); \
} while (false)
void srsran_sequence_state_gen_f(srsran_sequence_state_t* s, float value, float* out, uint32_t length)
{
uint32_t i = 0;
const float xor [2] = {+0.0F, -0.0F};
uint32_t i = 0;
if (length >= SEQUENCE_PAR_BITS) {
for (; i < length - (SEQUENCE_PAR_BITS - 1); i += SEQUENCE_PAR_BITS) {
@ -246,7 +253,7 @@ void srsran_sequence_state_gen_f(srsran_sequence_state_t* s, float value, float*
#endif
// Finish the parallel bits with generic code
for (; j < SEQUENCE_PAR_BITS; j++) {
*((uint32_t*)&out[i + j]) = *((uint32_t*)&value) ^ *((uint32_t*)&xor[(c >> j) & 1U]);
FLOAT_U32_XOR(out[i + j], value, (c << (31U - j)) & 0x80000000);
}
// Step sequences
@ -256,7 +263,7 @@ void srsran_sequence_state_gen_f(srsran_sequence_state_t* s, float value, float*
}
for (; i < length; i++) {
*((uint32_t*)&out[i]) = *((uint32_t*)&value) ^ *((uint32_t*)&xor[(s->x1 ^ s->x2) & 1U]);
FLOAT_U32_XOR(out[i], value, (s->x1 ^ s->x2) << 31U);
// Step sequences
s->x1 = sequence_gen_LTE_pr_memless_step_x1(s->x1);
@ -266,8 +273,7 @@ void srsran_sequence_state_gen_f(srsran_sequence_state_t* s, float value, float*
void srsran_sequence_state_apply_f(srsran_sequence_state_t* s, const float* in, float* out, uint32_t length)
{
uint32_t i = 0;
const float xor [2] = {+0.0F, -0.0F};
uint32_t i = 0;
if (length >= SEQUENCE_PAR_BITS) {
for (; i < length - (SEQUENCE_PAR_BITS - 1); i += SEQUENCE_PAR_BITS) {
@ -289,17 +295,17 @@ void srsran_sequence_state_apply_f(srsran_sequence_state_t* s, const float* in,
mask = _mm_and_si128(mask, (__m128i)_mm_set1_ps(-0.0F));
// Load input
__m128 v = _mm_load_ps(in + i + j);
__m128 v = _mm_loadu_ps(in + i + j);
// Loads input and perform sign XOR
v = _mm_xor_ps((__m128)mask, v);
_mm_storeu_ps(out + i + j, v);
}
#endif
#endif // LV_HAVE_SSE
// Finish the parallel bits with generic code
for (; j < SEQUENCE_PAR_BITS; j++) {
*((uint32_t*)&out[i + j]) = *((uint32_t*)&in[i + j]) ^ *((uint32_t*)&xor[(c >> j) & 1U]);
FLOAT_U32_XOR(out[i + j], in[i + j], (c << (31U - j)) & 0x80000000);
}
// Step sequences
@ -309,7 +315,7 @@ void srsran_sequence_state_apply_f(srsran_sequence_state_t* s, const float* in,
}
for (; i < length; i++) {
*((uint32_t*)&out[i]) = *((uint32_t*)&in[i]) ^ *((uint32_t*)&xor[(s->x1 ^ s->x2) & 1U]);
FLOAT_U32_XOR(out[i], in[i], (s->x1 ^ s->x2) << 31U);
// Step sequences
s->x1 = sequence_gen_LTE_pr_memless_step_x1(s->x1);
@ -744,7 +750,7 @@ void srsran_sequence_apply_packed(const uint8_t* in, uint8_t* out, uint32_t leng
out[i] = in[i] ^ reverse_lut[buffer & ((1U << rem8) - 1U) & 255U];
}
#else // SEQUENCE_PAR_BITS % 8 == 0
#else // SEQUENCE_PAR_BITS % 8 == 0
while (i < (length / 8 - (SEQUENCE_PAR_BITS - 1) / 8)) {
uint32_t c = (uint32_t)(x1 ^ x2);

Loading…
Cancel
Save