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function post_result = gt6DPostProcessOrientationSpread(test_data, result, disable_gtdisorientation, error_axes)
if (~exist('disable_gtdisorientation', 'var') || isempty(disable_gtdisorientation))
if (~exist('error_axes', 'var') || isempty(error_axes))
error_axes = [1 2 3];
end
fprintf('Post-processing theoretical reconstruction:\n')
c_in = c;
fprintf('- Cropping volume: ')
rec_size = [size(result.solution{1}, 1), size(result.solution{1}, 2), size(result.solution{1}, 3)];
result_size = [size(result.expected_dmvol, 1), size(result.expected_dmvol, 2), size(result.expected_dmvol, 3)];
lims = floor((rec_size - result_size) / 2) + 1;
lims = [lims, (lims + result_size - 1)];
post_result.recon = cell(size(result.solution));
num_vols = numel(post_result.recon);
sample_rate = 1000;
num_chars = fprintf('%04d/%04d', 0, num_vols);
for ii = 1:num_vols
if (mod(ii, sample_rate) == 0)
fprintf(repmat('\b', [1, num_chars]));
fprintf(repmat(' ', [1, num_chars]));
fprintf(repmat('\b', [1, num_chars]));
num_chars = fprintf('%04d/%04d', ii, num_vols);
end
post_result.recon{ii} = result.solution{ii}(lims(1):lims(4), lims(2):lims(5), lims(3):lims(6));
end
fprintf(repmat('\b', [1, num_chars]));
fprintf(repmat(' ', [1, num_chars]));
fprintf(repmat('\b', [1, num_chars]));
post_result.avg_orientations = result.ODF6D.voxels_avg_R_vectors(lims(1):lims(4), lims(2):lims(5), lims(3):lims(6), :);
tiles = gt6DComputeOrientationTiles(result.expected_dmvol, 5);
fprintf('\b\b: Done %d in %g s.\n- Merging Theoretical Deviations..', num_vols, toc(c))
post_result.domains_theo = gt6DTileDmvol(result.expected_dmvol, tiles);
fprintf('\b\b: Done in %g s.\n- Merging Reconstructed Deviations..', toc(c))
post_result.domains_recon = gt6DTileDmvol(post_result.avg_orientations, tiles);
fprintf('\b\b: Done in %g s.\n- Finding component-wise error Distance (quick)..', toc(c))
post_result.distance_comp_deg = 2 * atand(abs(result.expected_dmvol - post_result.avg_orientations));
fprintf('\b\b: Done in %g s.\n- Finding error Distance (quick)..', toc(c))
post_result.distance_deg_alt = result.expected_dmvol(:, :, :, error_axes) - post_result.avg_orientations(:, :, :, error_axes);
post_result.distance_deg_alt = 2 * atand(sqrt(sum(post_result.distance_deg_alt .^ 2, 4)));
post_result.distance_deg_alt = post_result.distance_deg_alt .* single(result.expected_seg);
fprintf('\b\b: Done in %g s.\n- Finding error Distance (exact)..', toc(c))
c = tic();
if (~disable_gtdisorientation)
post_result.distance_deg = get_disorientation(test_data, result, post_result.avg_orientations);
fprintf('\b\b: Done in %g s.\nDone in %g.\n', toc(c), toc(c_in))
function distances = get_disorientation(test_data, result, voxels_avg_R_vectors)
vol_size = size(result.expected_dmvol(:, :, :, 1));
theo_gvdm = gtDefDmvol2Gvdm(result.expected_dmvol);
reco_gvdm = gtDefDmvol2Gvdm(voxels_avg_R_vectors);
cryst = test_data.parameters.cryst;
symm = gtCrystGetSymmetryOperators(cryst.crystal_system, cryst.spacegroup);
num_vecs = size(theo_gvdm, 2);
chunk_size = 1000;
distances = zeros(num_vecs, 1);
for ii = 1:chunk_size:num_vecs
num_chars = fprintf('%04d/%04d', ii, num_vecs);
last_chunk_ind = min(num_vecs, ii + chunk_size - 1);
distances(ii:last_chunk_ind) = gtDisorientation( ...
theo_gvdm(:, ii:last_chunk_ind), ...
reco_gvdm(:, ii:last_chunk_ind), ...
symm, 'input', 'orimat', 'mode', 'passive');
fprintf(repmat('\b', [1 num_chars]));
fprintf(repmat(' ', [1 num_chars]));
fprintf(repmat('\b', [1 num_chars]));
distances = reshape(distances, vol_size);