complex float* compute_psf(unsigned int N, const long img2_dims[N], const long trj_dims[N], const complex float* traj, const complex float* weights)
{
long ksp_dims1[N];
md_select_dims(N, ~MD_BIT(0), ksp_dims1, trj_dims);
struct linop_s* op2 = nufft_create(N, ksp_dims1, img2_dims, trj_dims, traj, NULL,
nufft_conf_defaults, false);
complex float* ones = md_alloc(N, ksp_dims1, CFL_SIZE);
md_zfill(N, ksp_dims1, ones, 1.);
if (NULL != weights) {
md_zmul(N, ksp_dims1, ones, ones, weights);
md_zmulc(N, ksp_dims1, ones, ones, weights);
}
complex float* psft = md_alloc(N, img2_dims, CFL_SIZE);
linop_adjoint_unchecked(op2, psft, ones);
md_free(ones);
linop_free(op2);
return psft;
}
/**
* Wrapper for calling adjoint operation using italgos.
*/
extern void linop_adjoint_iter(void* _o, float* _dst, const float* _src)
{
struct linop_s* o = _o;
complex float* dst = (complex float*) _dst;
const complex float* src = (complex float*) _src;
linop_adjoint_unchecked(o, dst, src);
}
const struct operator_p_s* prox_normaleq_create(const struct linop_s* op, const complex float* y)
{
PTR_ALLOC(struct prox_normaleq_data, pdata);
SET_TYPEID(prox_normaleq_data, pdata);
PTR_ALLOC(struct iter_conjgrad_conf, cgconf);
*cgconf = iter_conjgrad_defaults;
cgconf->maxiter = 10;
cgconf->l2lambda = 0;
pdata->cgconf = PTR_PASS(cgconf);
pdata->op = op;
pdata->size = 2 * md_calc_size(linop_domain(op)->N, linop_domain(op)->dims);
pdata->adj = md_alloc_sameplace(1, &(pdata->size), FL_SIZE, y);
linop_adjoint_unchecked(op, (complex float*)pdata->adj, y);
return operator_p_create(linop_domain(op)->N, linop_domain(op)->dims,
linop_domain(op)->N, linop_domain(op)->dims,
CAST_UP(PTR_PASS(pdata)), prox_normaleq_apply, prox_normaleq_del);
}
static void nlop_adj_iter(iter_op_data* _o, float* _dst, const float* _src)
{
const struct iter4_nlop_s* nlop = CAST_DOWN(iter4_nlop_s, _o);
linop_adjoint_unchecked(nlop->nlop.derivative[0], (complex float*)_dst, (const complex float*)_src);
}
