#if SIMD_AVX || SIMD_SSE || SIMD_NEON
#define N (FIR_LENGTH>>2)
#define BEGINNING v4_t sum = vZero(); \
v4_t const * const __restrict coefs = (v4_t *)COEFS + N * rem;
#define _ sum = vMac(vLdu(at+j*4), coefs[j], sum), ++j;
#define END vStorSum(output+i, sum)
#define cc(n) case n: core(n); break
#define CORE(n) switch (n) {cc(2); cc(3); cc(4); cc(5); cc(6); default: core(n);}
#else
#define N FIR_LENGTH
#define BEGINNING sample_t sum = 0; \
sample_t const * const __restrict coefs = (sample_t *)COEFS + N * rem;
#define _ sum += coefs[j]*at[j], ++j;
#define END output[i] = sum
#define CORE(n) core(n)
#endif
#define core(n) \
for (i = 0; at < num_in * p->L; ++i, at += step) { \
int const div = at / p->L, rem = at % p->L; \
sample_t const * const __restrict at = input + div; \
int j = 0; BEGINNING; CONVOLVE(n); END;}
static void FUNCTION(stage_t * p, fifo_t * output_fifo)
{
int num_in = min(stage_occupancy(p), p->input_size);
if (num_in) {
sample_t const * input = stage_read_p(p);
int at = p->at.integer, step = p->step.integer;
int i, num_out = (num_in * p->L - at + step - 1) / step;
sample_t * __restrict output = fifo_reserve(output_fifo, num_out);
CORE(N);
assert(i == num_out);
fifo_read(&p->fifo, at / p->L, NULL);
p->at.integer = at % p->L;
}
}
#undef _
#undef CORE
#undef cc
#undef core
#undef N
#undef BEGINNING
#undef MIDDLE
#undef END
#undef CONVOLVE
#undef FIR_LENGTH
#undef FUNCTION