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normcorre.m
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normcorre.m
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function [M_final,shifts,template,options,col_shift] = normcorre(Y,options,template)
% online motion correction through DFT subpixel registration
% Based on the dftregistration.m function from Manuel Guizar and Jim Fienup
% INPUTS
% Y: Input data, can be already loaded in memory as a 3D
% tensor, a memory mapped file, or a pointer to a tiff stack
% options: options structure for motion correction (optional, rigid registration is performed if not provided)
% template: provide template (optional)
% OUTPUTS
% M_final: motion corrected data
% shifts: originally calculated shifts
% template: calculated template
% options: options structure (if modified)
% col_shift: relative shift due to bi-directional scanning
%% first determine filetype
nd = 2 + (options.d3 > 1); %max(length(sizY)-1,2); % determine whether imaging is 2d or 3d
if isa(Y,'char')
[~,~,ext] = fileparts(Y);
ext = ext(2:end);
if strcmpi(ext,'tif') || strcmpi(ext,'tiff')
tiffInfo = imfinfo(Y);
filetype = 'tif';
T = length(tiffInfo);
if nd == 3
sizY = [tiffInfo(1).Height,tiffInfo(1).Width,T,1];
else
sizY = [tiffInfo(1).Height,tiffInfo(1).Width,T];
end
elseif strcmpi(ext,'mat')
filetype = 'mem';
Y = matfile(Y,'Writable',true);
details = whos(Y);
var_sizes = [details.bytes];
[~,var_ind] = max(var_sizes);
var_name = details(var_ind).name;
sizY = size(Y,var_name);
elseif strcmpi(ext,'hdf5') || strcmpi(ext,'h5')
filetype = 'hdf5';
fileinfo = hdf5info(Y);
sizY = fileinfo.GroupHierarchy.Datasets.Dims;
end
elseif isobject(Y)
filetype = 'mem';
var_name = 'Y';
sizY = size(Y,var_name);
else % array loaded in memory
filetype = 'mat';
Y = single(Y);
sizY = size(Y);
end
if length(sizY) == nd
T = 1;
else
T = sizY(nd+1);
end
sizY = sizY(1:nd);
%% set default parameters if not present
if ~exist('options','var') || isempty(options)
options = NoRMCorreSetParms('d1',sizY(1),'d2',sizY(2));
if nd > 2; options.d3 = sizY(3); end
end
options.bin_width = min(options.bin_width,T+1);
options.mem_batch_size = min(options.mem_batch_size,T);
options.buffer_width = min(options.buffer_width,ceil(T/options.bin_width));
options.init_batch = min(options.init_batch,T);
memmap = options.memmap;
grid_size = options.grid_size;
mot_uf = options.mot_uf;
min_patch_size = options.min_patch_size;
overlap_pre = options.overlap_pre;
overlap_post = options.overlap_post;
upd_template = options.upd_template;
bin_width = options.bin_width;
buffer_width = options.buffer_width;
max_dev = options.max_dev;
init_batch = options.init_batch;
us_fac = options.us_fac;
method = options.method;
plot_flag = options.plot_flag*(nd==2);
filename = options.mem_filename;
use_parallel = options.use_parallel;
make_avi = options.make_avi;
name = options.name;
fr = options.fr;
iter = options.iter;
add_value = options.add_value;
max_shift = options.max_shift;
print_msg = options.print_msg;
if strcmpi(options.boundary,'nan')
fill_value = NaN;
else
fill_value = add_value;
end
%% first check for offset due to bi-directional scanning
if options.correct_bidir && isempty(options.col_shift)
col_shift = correct_bidirectional_offset(Y,options.nFrames,options.bidir_us);
elseif ~isempty(options.col_shift)
col_shift = options.col_shift;
else
col_shift = 0;
end
options.col_shift = col_shift;
if col_shift
if print_msg; fprintf('Offset %1.1d pixels due to bidirectional scanning detected. \n',col_shift); end
if strcmpi(options.shifts_method,'fft')
options.shifts_method = 'cubic';
if print_msg; fprintf('Cubic shifts will be applied. \n'); end
end
end
%% read initial batch and compute template
init_batch = min(T,init_batch);
interval = ceil(T/2-init_batch/2+1):floor(T/2+init_batch/2);
if exist('template','var')
init_batch = min(init_batch,1);
end
switch filetype
case 'tif'
Y_temp = read_file(Y,interval(1),init_batch,[],tiffInfo);
case 'hdf5'
Y_temp = read_file(Y,interval(1),init_batch);
case 'mem'
if nd == 2; Y_temp = Y.(var_name)(:,:,interval); elseif nd == 3; Y_temp = Y.(var_name)(:,:,:,interval); end
case 'mat'
if nd == 2; Y_temp = Y(:,:,interval); elseif nd == 3; Y_temp = Y(:,:,:,interval); end
end
data_type = class(Y_temp);
Y_temp = single(Y_temp);
if nargin < 3 || isempty(template)
if print_msg; fprintf('Registering the first %i frames just to obtain a good template....',init_batch); end
template_in = median(Y_temp,nd+1)+add_value;
fftTemp = fftn(template_in);
for t = 1:size(Y_temp,nd+1)
if nd == 2
[~,Greg] = dftregistration_min_max(fftTemp,fftn(Y_temp(:,:,t)),us_fac,-max_shift,max_shift,options.phase_flag);
end
if nd == 3
[~,Greg] = dftregistration_min_max_3d(fftTemp,fftn(Y_temp(:,:,:,t)),us_fac,-max_shift,max_shift,options.phase_flag);
end
M_temp = real(ifftn(Greg));
template_in = template_in*(t-1)/t + M_temp/t;
end
template_in = template_in + add_value;
if print_msg; fprintf('..done. \n'); end
else
template_in = single(template + add_value);
end
[d1,d2,d3,~] = size(Y_temp);
if nd == 2; d3 = 1; end
%% setup grids for patches
[xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,xx_us,xx_uf,yy_us,yy_uf,zz_us,zz_uf] = construct_grid(grid_size,mot_uf,d1,d2,d3,min_patch_size);
shifts = struct('shifts',cell(T,1),'shifts_up',cell(T,1),'diff',cell(T,1));
temp_cell = mat2cell_ov(template_in,xx_us,xx_uf,yy_us,yy_uf,zz_us,zz_uf,overlap_post,sizY);
%% precompute some quantities that are used repetitively for template matching and applying shifts
Nr = cell(size(temp_cell));
Nc = cell(size(temp_cell));
Np = cell(size(temp_cell));
Bs = cell(size(temp_cell));
for i = 1:length(xx_us)
for j = 1:length(yy_us)
for k = 1:length(zz_us)
[nr,nc,np] = size(temp_cell{i,j,k});
nr = ifftshift(-fix(nr/2):ceil(nr/2)-1);
nc = ifftshift(-fix(nc/2):ceil(nc/2)-1);
np = ifftshift(-fix(np/2):ceil(np/2)-1);
[Nc{i,j,k},Nr{i,j,k},Np{i,j,k}] = meshgrid(nc,nr,np);
extended_grid = [max(xx_us(i)-overlap_post(1),1),min(xx_uf(i)+overlap_post(1),d1),max(yy_us(j)-overlap_post(2),1),min(yy_uf(j)+overlap_post(2),d2),max(zz_us(k)-overlap_post(3),1),min(zz_uf(k)+overlap_post(3),d3)];
Bs{i,j,k} = permute(construct_weights([xx_us(i),xx_uf(i),yy_us(j),yy_uf(j),zz_us(k),zz_uf(k)],extended_grid),[2,1,3]);
end
end
end
if nd == 2; Np = cellfun(@(x) 0,Nr,'un',0); end
%%
%maxNumCompThreads(2);
template = mat2cell_ov(template_in,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY);
temp_mat = template_in;
fftTemp = cellfun(@fftn,template,'un',0);
fftTempMat = fftn(temp_mat);
if nd == 2; buffer = mat2cell_ov(zeros(d1,d2,bin_width,'single'),xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY); end
if nd == 3; buffer = mat2cell_ov(zeros(d1,d2,d3,bin_width,'single'),xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY); end
if ~strcmpi(options.output_type,'mat')
%options.mem_batch_size = min(round(options.mem_batch_size/bin_width)*bin_width,T);
if nd == 2; mem_buffer = zeros(d1,d2,options.mem_batch_size,'single'); end
if nd == 3; mem_buffer = zeros(d1,d2,d3,options.mem_batch_size,'single'); end
end
switch lower(options.output_type)
case 'mat'
M_final = zeros([sizY,T],data_type);
case 'memmap'
M_final = matfile(filename,'Writable',true);
if nd == 2; M_final.Y(d1,d2,T) = zeros(1,data_type); end
if nd == 3; M_final.Y(d1,d2,d3,T) = zeros(1,data_type); end
M_final.Yr(d1*d2*d3,T) = zeros(1,data_type);
case {'hdf5','h5'}
if exist(options.h5_filename,'file')
[pathstr,fname,ext] = fileparts(options.h5_filename);
new_filename = fullfile(pathstr,[fname,'_',datestr(now,30),ext]);
warning_msg = ['File ',options.h5_filename,'already exists. Saving motion corrected file as',new_filename];
warning('%s',warning_msg);
options.h5_filename = new_filename;
end
M_final = options.h5_filename;
if nd == 2
h5create(options.h5_filename,['/',options.h5_groupname],[d1,d2,Inf],'Chunksize',[d1,d2,options.mem_batch_size],'Datatype',data_type);
elseif nd == 3
h5create(options.h5_filename,['/',options.h5_groupname],[d1,d2,d3,Inf],'Chunksize',[d1,d2,d3,options.mem_batch_size],'Datatype',data_type);
end
case {'tif','tiff'}
M_final = options.tiff_filename;
opts_tiff.append = true;
opts_tiff.big = true;
if nd == 3
error('Saving volumetric tiff stacks is currently not supported. Use a different filetype');
end
otherwise
error('This filetype is currently not supported')
end
%%
if plot_flag
if make_avi
vidObj = VideoWriter(name);
set(vidObj,'FrameRate',fr);
open(vidObj);
end
if strcmpi(filetype,'mat')
nnY = quantile(Y(:),0.005);
mmY = quantile(Y(:),0.995);
else
nnY = quantile(Y_temp(:),0.005);
mmY = quantile(Y_temp(:),0.995);
end
fig = figure;
screensize = get(0,'Screensize' );
fac = min(min((screensize(3:4)-200)./[d2,d1]),10);
set(gcf, 'PaperUnits', 'points', 'Units', 'points');
set(gcf, 'Position', round([100 100 fac*d2 fac*d1]));
end
cnt_buf = 0;
if print_msg; fprintf('Template initialization complete. Now registering all the frames with new template. \n'); end
%%
prevstr = [];
for it = 1:iter
if it < iter; plot_flag = 0; else plot_flag = options.plot_flag; end
for t = 1:T
switch filetype
case 'tif'
Yt = single(imread(Y,'Index',t,'Info',tiffInfo));
case 'hdf5'
Yt = single(h5read(Y,'/mov',[ones(1,nd),t],[sizY(1:nd),1]));
case 'mem'
if nd == 2; Yt = single(Y.(var_name)(:,:,t)); end
if nd == 3; Yt = single(Y.(var_name)(:,:,:,t)); end
case 'mat'
if nd == 2; Yt = single(Y(:,:,t)); end
if nd == 3; Yt = single(Y(:,:,:,t)); end
end
minY = min(Yt(:));
maxY = max(Yt(:));
Yt = Yt + add_value;
ind = rem(t,bin_width) + bin_width*(rem(t,bin_width)==0);
Yc = mat2cell_ov(Yt,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY);
fftY = cellfun(@fftn, Yc, 'un',0);
M_fin = cell(length(xx_us),length(yy_us),length(zz_us)); %zeros(size(Y_temp));
shifts_temp = zeros(length(xx_s),length(yy_s),length(zz_s),nd);
diff_temp = zeros(length(xx_s),length(yy_s),length(zz_s));
if numel(M_fin) > 1
if nd == 2; out_rig = dftregistration_min_max(fftTempMat,fftn(Yt),us_fac,-max_shift,max_shift,options.phase_flag); lb = out_rig(3:4); ub = out_rig(3:4); end
if nd == 3; out_rig = dftregistration_min_max_3d(fftTempMat,fftn(Yt),1,-max_shift,max_shift,options.phase_flag); lb = out_rig(3:5); ub = out_rig(3:5); end
else
lb = -max_shift(1,nd);
ub = max_shift(1,nd);
max_dev = 0*max_dev;
end
if ~use_parallel
for i = 1:length(xx_s)
for j = 1:length(yy_s)
for k = 1:length(zz_s)
if nd == 2
%[output,Greg] = dftregistration_max(fftTemp{i,j,k},fftY{i,j,k},us_fac,max_shift);
[output,Greg] = dftregistration_min_max(fftTemp{i,j,k},fftY{i,j,k},us_fac,lb-max_dev(1:2),ub+max_dev(1:2),options.phase_flag);
elseif nd == 3
%[output,Greg] = dftregistration_max_3d(fftTemp{i,j,k},fftY{i,j,k},us_fac,max_shift);
[output,Greg] = dftregistration_min_max_3d(fftTemp{i,j,k},fftY{i,j,k},us_fac,lb-max_dev,ub+max_dev,options.phase_flag);
shifts_temp(i,j,k,3) = output(5);
end
M_temp = real(ifftn(Greg));
M_temp = remove_boundaries(M_temp,output(3:end),'copy',template{i,j,k});
if nd == 2; buffer{i,j,k}(:,:,ind) = M_temp; end
if nd == 3; buffer{i,j,k}(:,:,:,ind) = M_temp; end
shifts_temp(i,j,k,1) = output(3);
shifts_temp(i,j,k,2) = output(4);
diff_temp(i,j,k) = output(2);
if all([length(xx_s),length(yy_s),length(zz_s)] == 1)
M_fin{i,j,k} = remove_boundaries(M_temp,output(3:end),options.boundary,template{i,j,k},add_value);
end
end
end
end
else
Mt2 = cell(length(xx_s)*length(yy_s)*length(zz_s),1);
shifts_cell = cell(length(xx_s)*length(yy_s)*length(zz_s),1);
diff_cell = cell(length(xx_s)*length(yy_s)*length(zz_s),1);
for ii = length(xx_s)*length(yy_s)*length(zz_s):-1:1
[i,j,k] = ind2sub([length(xx_s),length(yy_s),length(zz_s)],ii);
if nd == 2; future_results(ii) = parfeval(@dftregistration_min_max,2,fftTemp{i,j,k},fftY{i,j,k},us_fac,lb-max_dev(1:2),ub+max_dev(1:2),options.phase_flag); end
if nd == 3; future_results(ii) = parfeval(@dftregistration_min_max_3d,2,fftTemp{i,j,k},fftY{i,j,k},us_fac,lb-max_dev,ub+max_dev,options.phase_flag); end
end
for i = 1:length(xx_s)*length(yy_s)*length(zz_s)
[ii,output,Greg] = fetchNext(future_results);
M_temp = real(ifftn(Greg));
Mt2{ii} = M_temp;
shifts_cell{ii} = output(3:end);
diff_cell{ii} = output(2);
end
% parfor ii = 1:length(xx_s)*length(yy_s)*length(zz_s)
% [i,j,k] = ind2sub([length(xx_s),length(yy_s),length(zz_s)],ii);
% %if nd == 2; [output,Greg] = dftregistration_max(fftTemp{i,j,k},fftY{i,j,k},us_fac,max_shift); end
% %if nd == 3; [output,Greg] = dftregistration_max_3d(fftTemp{i,j,k},fftY{i,j,k},us_fac,max_shift); end
% if nd == 2; [output,Greg] = dftregistration_min_max(fftTemp{i,j,k},fftY{i,j,k},us_fac,lb-max_dev(1:2),ub+max_dev(1:2),options.phase_flag); end
% if nd == 3; [output,Greg] = dftregistration_min_max_3d(fftTemp{i,j,k},fftY{i,j,k},us_fac,lb-max_dev,ub+max_dev,options.phase_flag); end
% M_temp = real(ifftn(Greg));
% Mt2{ii} = M_temp;
% shifts_cell{ii} = output(3:end);
% diff_cell{ii} = output(2);
% end
for ii = 1:length(xx_s)*length(yy_s)*length(zz_s)
[i,j,k] = ind2sub([length(xx_s),length(yy_s),length(zz_s)],ii);
if nd == 2; buffer{i,j,k}(:,:,ind) = Mt2{ii}; end
if nd == 3; buffer{i,j,k}(:,:,:,ind) = Mt2{ii}; end
if mot_uf == 1
M_fin{i,j,k} = Mt2{ii};
end
shifts_temp(i,j,k,:) = shifts_cell{ii};
diff_temp(i,j,k) = diff_cell{ii};
end
end
shifts(t).shifts = shifts_temp;
shifts(t).diff = diff_temp;
switch lower(options.shifts_method)
case 'fft'
if any([length(xx_s),length(yy_s),length(zz_s)] > 1)
if ~isfield(options,'shifts_method'); options.shifts_method = 'FFT'; end
if mot_uf(3) > 1
do = [length(xx_us),length(yy_us),length(zz_us)]./[length(xx_s),length(yy_s),length(zz_s)];
ds = [length(xx_s),length(yy_s),length(zz_s)];
dim = [length(xx_us),length(yy_us),length(zz_us)];
[Xq,Yq,Zq] = meshgrid(linspace((1+1/do(2))/2,ds(2)+(1-1/do(2))/2,dim(2)),linspace((1+1/do(1))/2,ds(1)+(1-1/do(1))/2,dim(1)),linspace((1+1/do(3))/2,ds(3)+(1-1/do(3))/2,dim(3)));
%tform = affine3d(diag([mot_uf(:);1]));
%tform = affine3d(diag([mot_uf([2,1,3])';1]));
%diff_up = imwarp(diff_temp,tform,'OutputView',imref3d([length(xx_uf),length(yy_uf),length(zz_uf)]));
%diff_up = imwarp(diff_temp,tform,'OutputView',imref3d([length(xx_uf),length(yy_uf),length(zz_uf)]),'SmoothEdges',true);
diff_up = interp3(diff_temp,Xq,Yq,Zq,'makima');
shifts_up = zeros([size(diff_up),3]);
%for dm = 1:3; shifts_up(:,:,:,dm) = imwarp(shifts_temp(:,:,:,dm),tform,'OutputView',imref3d([length(xx_uf),length(yy_uf),length(zz_uf)]),'SmoothEdges',true); end
for dm = 1:3; shifts_up(:,:,:,dm) = interp3(shifts_temp(:,:,:,dm),Xq,Yq,Zq,'makima'); end
else
shifts_up = imresize(shifts_temp,[length(xx_uf),length(yy_uf)]);
diff_up = imresize(diff_temp,[length(xx_uf),length(yy_uf)]);
end
shifts(t).shifts_up = shifts_up;
shifts(t).diff = diff_up;
for i = 1:length(xx_uf)
for j = 1:length(yy_uf)
for k = 1:length(zz_uf)
extended_grid = [max(xx_us(i)-overlap_post(1),1),min(xx_uf(i)+overlap_post(1),d1),max(yy_us(j)-overlap_post(2),1),min(yy_uf(j)+overlap_post(2),d2),max(zz_us(k)-overlap_post(3),1),min(zz_uf(k)+overlap_post(3),d3)];
I_temp = Yt(extended_grid(1):extended_grid(2),extended_grid(3):extended_grid(4),extended_grid(5):extended_grid(6));
M_fin{i,j,k} = shift_reconstruct(I_temp,shifts_up(i,j,k,:),diff_up(i,j,k),us_fac,Nr{i,j,k},Nc{i,j,k},Np{i,j,k},options.boundary,add_value);
%M_fin{i,j,k} = shift_reconstruct2(I_temp,shifts_up(i,j,k,:),'bilinear',diff_up(i,j,k),us_fac,Nr{i,j,k},Nc{i,j,k},Np{i,j,k},options.boundary,add_value);
end
end
end
else
shifts_up = shifts_temp;
shifts(t).shifts_up = shifts(t).shifts;
end
gx = max(abs(reshape(diff(shifts_up,[],1),[],1)));
gy = max(abs(reshape(diff(shifts_up,[],2),[],1)));
gz = max(abs(reshape(diff(shifts_up,[],3),[],1)));
flag_interp = max([gx;gy;gz;0])<0.5; % detect possible smearing
if flag_interp
Mf = cell2mat_ov_sum(M_fin,xx_us,xx_uf,yy_us,yy_uf,zz_us,zz_uf,overlap_post,sizY,Bs) - add_value;
else
Mf = cell2mat_ov(M_fin,xx_us,xx_uf,yy_us,yy_uf,zz_us,zz_uf,overlap_post,sizY) - add_value;
end
otherwise
shifts(t).shifts_up = shifts(t).shifts;
if nd == 3
shifts_up = zeros([options.d1,options.d2,options.d3,3]);
do = size(shifts_up)./size(shifts_temp);
ds = size(shifts_temp);
dim = [options.d1,options.d2,options.d3];
if (0)
[Xq,Yq,Zq] = meshgrid(linspace(1,ds(2),dim(2)),linspace(1,ds(1),dim(1)),linspace(1,ds(3),dim(3)));
else
[Xq,Yq,Zq] = meshgrid(linspace((1+1/do(2))/2,ds(2)+(1-1/do(2))/2,dim(2)),linspace((1+1/do(1))/2,ds(1)+(1-1/do(1))/2,dim(1)),linspace((1+1/do(3))/2,ds(3)+(1-1/do(3))/2,dim(3)));
Xq(Xq<1)=1; Xq(Xq>dim(2))=dim(2);
Yq(Yq<1)=1; Yq(Yq>dim(1))=dim(1);
Zq(Zq<1)=1; Zq(Zq>dim(3))=dim(3);
end
if numel(shifts_temp) > 3
for dm = 1:3; shifts_up(:,:,:,dm) = interp3(shifts_temp(:,:,:,dm),Xq,Yq,Zq,'makima'); end
%tform = affine3d(diag([do([2,1,3])';1]));
%for dm = 1:3; shifts_up(:,:,:,dm) = imwarp(shifts_temp(:,:,:,dm),tform,'OutputView',imref3d([options.d1,options.d2,options.d3]),'SmoothEdges',true); end
else
for dm = 1:3; shifts_up(:,:,:,dm) = shifts_temp(dm); end
end
shifts_up(2:2:end,:,:,2) = shifts_up(2:2:end,:,:,2) + col_shift;
Mf = imwarp(Yt,-cat(4,shifts_up(:,:,:,2),shifts_up(:,:,:,1),shifts_up(:,:,:,3)),options.shifts_method,'FillValues',fill_value);
else
shifts_up = imresize(shifts_temp,[options.d1,options.d2]);
shifts_up(2:2:end,:,2) = shifts_up(2:2:end,:,2) + col_shift;
Mf = imwarp(Yt,-cat(3,shifts_up(:,:,2),shifts_up(:,:,1)),options.shifts_method,'FillValues',fill_value);
end
Mf(Mf<minY) = minY;
Mf(Mf>maxY) = maxY;
end
if ~strcmpi(options.output_type,'mat')
rem_mem = rem(t,options.mem_batch_size);
if rem_mem == 0; rem_mem = options.mem_batch_size; end
if nd == 2; mem_buffer(:,:,rem_mem) = cast(Mf,data_type); end
if nd == 3; mem_buffer(:,:,:,rem_mem) = cast(Mf,data_type); end
end
switch lower(options.output_type)
case 'mat'
if nd == 2; M_final(:,:,t) = cast(Mf,data_type); end
if nd == 3; M_final(:,:,:,t) = cast(Mf,data_type); end
case 'memmap'
if rem_mem == options.mem_batch_size || t == T
if nd == 2; M_final.Y(:,:,t-rem_mem+1:t) = mem_buffer(:,:,1:rem_mem); end
if nd == 3; M_final.Y(:,:,:,t-rem_mem+1:t) = mem_buffer(:,:,:,1:rem_mem); end
M_final.Yr(:,t-rem_mem+1:t) = reshape(mem_buffer(1:d1*d2*d3*rem_mem),d1*d2*d3,rem_mem);
end
case {'hdf5','h5'}
if rem_mem == options.mem_batch_size || t == T
if nd == 2; h5write(options.h5_filename,['/',options.h5_groupname],mem_buffer(:,:,1:rem_mem),[ones(1,nd),t-rem_mem+1],[sizY(1:nd),rem_mem]); end
if nd == 3; h5write(options.h5_filename,['/',options.h5_groupname],mem_buffer(:,:,:,1:rem_mem),[ones(1,nd),t-rem_mem+1],[sizY(1:nd),rem_mem]); end
end
case {'tif','tiff'}
if rem_mem == options.mem_batch_size || t == T
saveastiff(cast(mem_buffer(:,:,1:rem_mem),data_type),options.tiff_filename,opts_tiff);
end
end
if mod(t,bin_width) == 0 && upd_template
if print_msg
str=[num2str(t), ' out of ', num2str(T), ' frames registered, iteration ', num2str(it), ' out of ', num2str(iter), '..'];
refreshdisp(str, prevstr, t);
prevstr=str;
%fprintf('%i out of %i frames registered, iteration %i out of %i \n',t,T,it,iter)
end
cnt_buf = cnt_buf + 1;
if strcmpi(method{2},'mean')
new_temp = cellfun(@(x) nanmean(x,nd+1), buffer, 'UniformOutput',false);
elseif strcmpi(method{2},'median');
new_temp = cellfun(@(x) nanmedian(x,nd+1), buffer, 'UniformOutput', false);
end
if strcmpi(method{1},'mean')
cnt = t/bin_width + 1;
template = cellfun(@plus, cellfun(@(x) x*(cnt-1)/cnt, template,'un',0), cellfun(@(x) x*1/cnt, new_temp,'un',0), 'un',0);
elseif strcmpi(method{1},'median');
if cnt_buf <= buffer_width
if nd == 2; buffer_med(:,:,cnt_buf) = cell2mat_ov(new_temp,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY); end
if nd == 3; buffer_med(:,:,:,cnt_buf) = cell2mat_ov(new_temp,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY); end
else
buffer_med = circshift(buffer_med,[zeros(1,nd),-1]);
if nd == 2; buffer_med(:,:,buffer_width) = cell2mat_ov(new_temp,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY); end
if nd == 3; buffer_med(:,:,:,buffer_width) = cell2mat_ov(new_temp,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY); end
end
template = mat2cell_ov(nanmedian(buffer_med,nd+1),xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY);
end
fftTemp = cellfun(@fftn, template, 'un',0);
temp_mat = cell2mat_ov(template,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY);
fftTempMat = fftn(temp_mat);
end
if plot_flag && mod(t,1) == 0
subplot(221); imagesc(Yt-add_value,[nnY,mmY]); title('Raw data','fontweight','bold','fontsize',14);
xlabel(sprintf('Frame %i out of %i',t,T),'fontweight','bold','fontsize',14); set(gca,'Xtick',[],'Ytick',[]);
subplot(222); imagesc(Mf,[nnY,mmY]); title('Motion Corrected','fontweight','bold','fontsize',14); colormap('bone'); axis off;
subplot(223); quiver(shifts_up(:,:,:,1),shifts_up(:,:,:,2),'Autoscale','off'); title('Motion vector field','fontweight','bold','fontsize',14); axis off;
subplot(224); imagesc(cell2mat_ov(template,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY)-add_value,[nnY,mmY]); title('Matching Template','fontweight','bold','fontsize',14); axis off
drawnow;
if make_avi
currFrame = getframe(fig);
writeVideo(vidObj,currFrame);
end
end
end
if print_msg; fprintf('\n'); end
if it == iter
template = cellfun(@(x) x - add_value,template,'un',0);
template = cell2mat_ov(template,xx_s,xx_f,yy_s,yy_f,zz_s,zz_f,overlap_pre,sizY);
end
if memmap
M_final.shifts = shifts;
M_final.template = template;
end
if make_avi && plot_flag
close(vidObj);
end
maxNumCompThreads('automatic');
if print_msg; fprintf('done. \n'); end
end