Mercurial > hg > camir-aes2014
view toolboxes/MIRtoolbox1.3.2/MIRToolbox/@mirdesign/evaleach.m @ 0:e9a9cd732c1e tip
first hg version after svn
| author | wolffd |
|---|---|
| date | Tue, 10 Feb 2015 15:05:51 +0000 |
| parents | |
| children |
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function [y d2] = evaleach(d,single,name) % Top-down traversal of the design flowchart, at the beginning of the % evaluation phase. % Called by mirfunction, mireval, mirframe and mirsegment. % This is during that traversal that we check whether a chunk decomposition % needs to be performed or not, and carry out that chunk decomposition. if nargin<3 || isempty(name) if not(ischar(d.method)) name = func2str(d.method); end end if nargin<2 single = 0; end CHUNKLIM = mirchunklim; f = d.file; fr = d.frame; frnochunk = isfield(d.frame,'dontchunk'); frchunkbefore = isfield(d.frame,'chunkbefore'); sg = d.segment; sr = d.sampling; sr2 = d.resampling; w = d.size; lsz = w(2)-w(1)+1; len = lsz/sr; if ischar(sg) error('ERROR in MIREVAL: mirsegment of design object accepts only array of numbers as second argument.'); end if not(isempty(sg)) over = find(sg(2,:) > len); if not(isempty(over)) sg = sg(:,1:over-1); end end a = d.argin; ch = d.chunk; chan = d.channel; specif = d.specif; if isaverage(specif) specif.eachchunk = 'Normal'; end if ischar(a) % The top-down traversal of the design flowchart now reaches the lowest % layer, i.e., audio file loading. % Now the actual evaluation will be carried out bottom-up. if isempty(ch) % No chunk decomposition y = miraudio(f,'Now',[w(:)' 0 chan]); else % Chunk decomposition y = miraudio(f,'Now',[ch(1),ch(2) 0 chan]); end if not(isempty(d.postoption)) && d.postoption.mono y = miraudio(y,'Mono',1); end y = set(y,'AcrossChunks',get(d,'AcrossChunks')); d2 = d; elseif d.chunkdecomposed && isempty(d.tmpfile) % Already in a chunk decomposition process [y d2] = evalnow(d); elseif isempty(fr) || frnochunk || not(isempty(sg)) %% WHAT ABOUT CHANNELS? % No frame or segment decomposition in the design to evaluate % (Or particular frame decomposition, where chunks are not distributed to children (frnochunk).) if not(isfield(specif,'eachchunk')) ... || d.nochunk ... || (not(isempty(single)) && isnumeric(single) && single > 1 ... && isfield(specif,'combinechunk') ... && iscell(specif.combinechunk)) chunks = []; elseif not(isempty(sg)) meth = 'Segment '; if size(sg,1) == 1 chunks = floor(sg(1:end-1)*sr)+1; chunks(2,:) = min( floor(sg(2:end)*sr)-1,lsz-1)+1; else chunks = floor(sg*sr); chunks(1,:) = chunks(1,:)+1; end else meth = 'Chunk '; if isempty(fr) if lsz > CHUNKLIM % The required memory exceed the max memory threshold. nch = ceil(lsz/CHUNKLIM); %%% TAKE INTO CONSIDERATION NUMBER OF CHANNELS; ETC... chunks = max(0,lsz-CHUNKLIM*(nch:-1:1))+w(1); chunks(2,:) = lsz-CHUNKLIM*(nch-1:-1:0)+w(1)-1; else chunks = []; end else chunks = compute_frames(fr,sr,sr2,w,lsz,CHUNKLIM,d.overlap); end end if not(isempty(chunks)) % The chunk decomposition is performed. nch = size(chunks,2); d = callbeforechunk(d,d,w,lsz); % Some optional initialisation tmp = []; if mirwaitbar h = waitbar(0,['Computing ' name]); else h = 0; end if not(isempty(d.tmpfile)) && d.tmpfile.fid == 0 % When applicable, a new temporary file is created. d.tmpfile.fid = fopen('tmpfile.mirtoolbox','w'); end tmpfile = []; if not(d.ascending) chunks = fliplr(chunks); end afterpostoption = d.postoption; % Used only when: % - eachchunk is set to 'Normal', % - combinechunk is not set to 'Average', and % - no afterchunk field has been specified. % afterpostoption will be used for the final call % to the method after the chunk decomposition. method = d.method; if ischar(specif.eachchunk) && strcmpi(specif.eachchunk,'Normal') if not(isempty(d.postoption)) pof = fieldnames(d.postoption); for o = 1:length(pof) if isfield(specif.option.(pof{o}),'chunkcombine') afterpostoption = rmfield(afterpostoption,pof{o}); else d.postoption = rmfield(d.postoption,pof{o}); end end end else method = specif.eachchunk; end d2 = d; d2.method = method; y = {}; for i = 1:size(chunks,2) disp([meth,num2str(i),'/',num2str(nch),'...']) d2 = set(d2,'Chunk',[chunks(1,i) chunks(2,i) (i == size(chunks,2))]); if not(ischar(specif.eachchunk) && ... strcmpi(specif.eachchunk,'Normal')) if frnochunk d2.postoption = 0; else diffchunks = diff(chunks); % Usual chunk size d2.postoption = max(diffchunks) - diffchunks(i); % Reduction of the current chunk size to be taken into % consideration in mirspectrum, for instance, using % zeropadding end end d2 = set(d2,'InterChunk',tmp); d2.chunkdecomposed = 1; [ss d3] = evalnow(d2); if iscell(ss) && not(isempty(ss)) tmp = get(ss{1},'InterChunk'); elseif isstruct(ss) tmp = []; else tmp = get(ss,'InterChunk'); end % d2 is like d3 except that its argument is now evaluated. d3.postoption = d.postoption; % Pas joli joli d3.method = method; d2 = d3; % This new argument is transfered to d y = combinechunk_noframe(y,ss,sg,i,d2,chunks,single); clear ss if h if not(d.ascending) close(h) h = waitbar((chunks(1,i)-chunks(1,end))/chunks(2,1),... ['Computing ' func2str(d.method) ' (backward)']); else waitbar((chunks(2,i)-chunks(1))/chunks(end),h) end end end y = afterchunk_noframe(y,lsz,d,afterpostoption,d2); % Final operations to be executed after the chunk decomposition if isa(d,'mirstruct') && ... (isempty(d.frame) || isfield(d.frame,'dontchunk')) y = evalbranches(d,y); end if h close(h) end drawnow else % No chunk decomposition [y d2] = evalnow(d); if isa(d,'mirstruct') && isfield(d.frame,'dontchunk') y = evalbranches(d,y); end end elseif d.nochunk [y d2] = evalnow(d); else % Frame decomposition in the design to be evaluated. chunks = compute_frames(fr,sr,sr2,w,lsz,CHUNKLIM,d.overlap); if size(chunks,2)>1 % The chunk decomposition is performed. if mirwaitbar h = waitbar(0,['Computing ' name]); else h = 0; end inter = []; d = set(d,'FrameDecomposition',1); d2 = d; nch = size(chunks,2); y = {}; if frchunkbefore d2after = d2; d2.method = d2.argin.method; d2.option = d2.argin.option; d2.postoption = d2.argin.postoption; d2.argin = d2.argin.argin; end for fri = 1:nch % For each chunk... disp(['Chunk ',num2str(fri),'/',num2str(nch),'...']) d2 = set(d2,'Chunk',chunks(:,fri)'); d2 = set(d2,'InterChunk',inter); %d2.postoption = []; [res d2] = evalnow(d2); if not(isempty(res)) if iscell(res) inter = get(res{1},'InterChunk'); elseif not(isstruct(res)) inter = get(res,'InterChunk'); res = {res}; end end y = combinechunk_frame(y,res,d2,fri); if h waitbar(chunks(2,fri)/chunks(end),h); end end if frchunkbefore y = d2after.method(y,d2after.option,d2after.postoption); end if isa(d,'mirstruct') && get(d,'Stat') y = mirstat(y); end if h close(h) end else % No chunk decomposition [y d2] = evalnow(d); end end if iscell(y) for i = 1:length(y) if not(isempty(y{i}) || isstruct(y{i})) if iscell(y{i}) for j = 1:length(y{i}) y{i}{j} = set(y{i}{j},'InterChunk',[]); end else y{i} = set(y{i},'InterChunk',[]); end end end end function chunks = compute_frames(fr,sr,sr2,w,lsz,CHUNKLIM,frov) if strcmpi(fr.length.unit,'s') fl = fr.length.val*sr; fl2 = fr.length.val*sr2; elseif strcmpi(fr.length.unit,'sp') fl = fr.length.val; fl2 = fl; end if strcmpi(fr.hop.unit,'/1') h = fr.hop.val*fl; h2 = fr.hop.val*fl2; elseif strcmpi(fr.hop.unit,'%') h = fr.hop.val*fl*.01; h2 = fr.hop.val*fl2*.01; elseif strcmpi(fr.hop.unit,'s') h = fr.hop.val*sr; h2 = fr.hop.val*sr2; elseif strcmpi(fr.hop.unit,'sp') h = fr.hop.val; h2 = fr.hop.val; elseif strcmpi(fr.hop.unit,'Hz') h = sr/fr.hop.val; h2 = sr2/fr.hop.val; end n = floor((lsz-fl)/h)+1; % Number of frames if n < 1 %warning('WARNING IN MIRFRAME: Frame length longer than total sequence size. No frame decomposition.'); fp = w; fp2 = (w-1)/sr*sr2+1; else st = floor(((1:n)-1)*h)+w(1); st2 = floor(((1:n)-1)*h2)+w(1); fp = [st; floor(st+fl-1)]; fp(:,fp(2,:)>w(2)) = []; fp2 = [st2; floor(st2+fl2-1)]; fp2(:,fp2(2,:)>(w(2)-w(1))/sr*sr2+w(2)) = []; end fpe = (fp2-1)/sr2-(fp-1)/sr; %Rounding error if resampling fpsz = (fp(2,1)-fp(1,1)) * n; % Total number of samples fpsz2 = (fp2(2,1)-fp2(1,1)) * n; % Total number of samples if max(fpsz,fpsz2) > CHUNKLIM % The required memory exceed the max memory threshold. nfr = size(fp,2); % Total number of frames frch = max(ceil(CHUNKLIM/(fp(2,1)-fp(1,1))),2); % Number of frames per chunk frch = max(frch,frov*2); [unused cut] = min(abs(fpe(1,frch:-1:1))); %frch = frch - cut; % this correspond to the frame with less rounding error nch = ceil((nfr-frch)/(frch-frov))+1; % Number of chunks chbeg = (frch-frov)*(0:nch-1)+1; % First frame in the chunk chend = (frch-frov)*(0:nch-1)+frch; % Last frame in the chunk chend = min(chend,nfr); if frov > 1 chbeg = chend-frch+1; end chunks = [fp(1,chbeg) ; fp(2,chend)+1]; % After resampling, one sample may be missing, leading to a complete frame drop. chunks(end) = min(chunks(end),fp(end)); % Last chunk should not extend beyond audio size. else chunks = []; end function res = combinechunk_frame(old,new,d2,fri) if isempty(mirgetdata(new)) res = old; return end if isstruct(old) f = fields(old); for i = 1:length(f) res.(f{i}) = combinechunk_frame(old.(f{i}),new.(f{i}),d2,fri); end return end if fri == 1 res = new; elseif isfield(d2,'specif') && isfield(d2.specif,'combineframes') res = d2.specif.combineframes(old{1},new{1}); else res = combineframes(old,new); end function res = combinechunk_noframe(old,new,sg,i,d2,chunks,single) if isempty(new) res = {}; return end if isempty(mirgetdata(new)) res = old; return end if not(iscell(new)) new = {new}; end if not(iscell(old)) old = {old}; end if not(isempty(old)) && isstruct(old{1}) f = fields(old{1}); for j = 1:length(f) index.type = '.'; index.subs = f{j}; res.(f{j}) = combinechunk_noframe(old{1}.(f{j}),new{1}.(f{j}),... sg,i,subsref(d2,index),chunks,single); end return end if ischar(single) && not(isempty(old)) old = {old{1}}; end if isempty(sg) if isaverage(d2.specif) % Measure total size for later averaging if iscell(new) new1 = new{1}; else new1 = new; end dnew = get(new1,'Data'); dnew = mircompute(@multweight,dnew,chunks(2,i)-chunks(1,i)+1); if iscell(new) new{1} = set(new1,'Data',dnew); else new = set(new1,'Data',dnew); end end %tmp = get(new{1},'InterChunk'); if not(isempty(d2.tmpfile)) && d2.tmpfile.fid > 0 % If temporary file is used, chunk results are written % in the file if i < size(chunks,2) ds = get(new{1},'Data'); ps = get(new{1},'Pos'); % ftell(d2.tmpfile.fid) count = fwrite(d2.tmpfile.fid,ds{1}{1},'double'); count = fwrite(d2.tmpfile.fid,ps{1}{1},'double'); % ftell(d2.tmpfile.fid) clear ds ps end res = new; else % Else, chunk results are directly combined in active % memory if i == 1 res = new; else if isfield(d2.specif,'combinechunk') if not(iscell(d2.specif.combinechunk)) method = {d2.specif.combinechunk}; else method = d2.specif.combinechunk; end for z = 1:length(old) if isframed(old{z}) res(z) = combineframes(old{z},new{z}); elseif ischar(method{z}) if strcmpi(method{z},'Concat') res{z} = concatchunk(old{z},new{z},d2.ascending); elseif strcmpi(method{z},'Average') res{z} = sumchunk(old{z},new{z}); else error(['SYNTAX ERROR: ',... method{z},... ' is not a known keyword for combinechunk.']); end else res{z} = method{z}(old{z},new{z}); end end else for z = 1:length(old) if isframed(old{z}) res(z) = combineframes(old{z},new{z}); else mirerror('MIREVAL','Chunk recombination in non-framed mode is not available for all features yet. Please turn off the chunk decomposition.'); end end end end end else if i == 1 res = new; else for z = 1:length(old) res{z} = combinesegment(old{z},new{z}); end end end function res = afterchunk_noframe(input,lsz,d,afterpostoption,d2) if isstruct(input) %mirerror('MIREVAL','Sorry, mirstruct only accepts frame-decomposed objects as ''tmp'' fields.'); res = input; %f = fields(input); %for i = 1:length(f) % index.type = '.'; % index.subs = f{i}; % res.(f{i}) = afterchunk_noframe(input.(f{i}),lsz,... % subsref(d,index),afterpostoption,subsref(d2,index)); %end return end if isfield(d2.specif,'afterchunk') res{1} = d2.specif.afterchunk(input{1},lsz,d.postoption); elseif isaverage(d2.specif) res{1} = divideweightchunk(input{1},lsz); elseif not(isempty(afterpostoption)) && isempty(d2.tmpfile) res{1} = d.method(input{1},[],afterpostoption); else res = input; end if not(isempty(d2.tmpfile)) adr = ftell(d2.tmpfile.fid); fclose(d2.tmpfile.fid); ytmpfile.fid = fopen('tmpfile.mirtoolbox'); fseek(ytmpfile.fid,adr,'bof'); ytmpfile.data = input{1}; ytmpfile.layer = 0; res{1} = set(input{1},'TmpFile',ytmpfile); end function old = combineframes(old,new) if not(iscell(old)) old = {old}; end if not(iscell(new)) new = {new}; end for var = 1:length(new) ov = old{var}; nv = new{var}; if isa(ov,'mirscalar') ov = combinedata(ov,nv,'Data'); ov = combinedata(ov,nv,'Mode'); if isa(ov,'mirpitch') ov = combinedata(ov,nv,'Amplitude'); end else if isa(ov,'mirtemporal') [ov omatch nmatch] = combinedata(ov,nv,'Time',[],[],@modiftime); else [ov omatch nmatch] = combinedata(ov,nv,'Pos',[],[]); if isa(ov,'mirspectrum') [ov omatch nmatch] = combinedata(ov,nv,'Phase',[],[]); end end ov = combinedata(ov,nv,'Data',omatch,nmatch); end ov = combinedata(ov,nv,'FramePos'); ov = combinedata(ov,nv,'PeakPos'); ov = combinedata(ov,nv,'PeakVal'); ov = combinedata(ov,nv,'PeakMode'); old{var} = ov; end function [ov omatch nmatch] = combinedata(ov,nv,key,omatch,nmatch,modifdata) if isstruct(ov) omatch = []; nmatch = []; f = fields(ov); for i = 1:length(f) ov.(f{i}) = combinedata(ov.(f{i}),nv.(f{i}),key); end return end odata = get(ov,key); if isempty(odata) || isempty(odata{1}) return end odata = odata{1}; if iscell(odata) if ischar(odata{1}) return else odata = odata{1}; end end ndata = get(nv,key); ndata = ndata{1}; if iscell(ndata) ndata = ndata{1}; end if nargin>3 if isempty(omatch) ol = size(odata,1); nl = size(ndata,1); unmatch = ol-nl; if unmatch>0 [unused idx] = min(odata(1:1+unmatch,1,1)-ndata(1)); omatch = idx:idx+nl-1; nmatch = 1:nl; elseif unmatch<0 [unused idx] = min(ndata(1:1-unmatch,1,1)-odata(1)); nmatch = idx:idx+ol-1; omatch = 1:ol; else nmatch = 1:nl; omatch = 1:ol; end end odata(omatch,end+1:end+size(ndata,2),:,:) = ndata(nmatch,:,:,:); %4.D for keysom else odata(:,end+1:end+size(ndata,2),:,:) = ndata; end ov = set(ov,key,{{odata}}); %{odata} for warped chromagram for instance.... function d = modiftime(d,p) d = d + p; function [y d] = evalnow(d) % Go one step further in the top-down evaluation initialisation argin = d.argin; if not(iscell(argin)) argin = {argin}; end for i = 1:length(argin) a = argin{i}; if not(d.ascending) a.ascending = 0; end if isa(a,'mirdata') % Input already computed tmpfile = get(a,'TmpFile'); if not(isempty(tmpfile)) && tmpfile.fid > 0 % The input can be read from the temporary file ch = get(d,'Chunk'); a = tmpfile.data; a = set(a,'InterChunk',get(d,'InterChunk'),'TmpFile',tmpfile); channels = get(a,'Channels'); channels = length(channels{1}); if not(channels) channels = 1; end size = (ch(2)-ch(1)+1); current = ftell(tmpfile.fid); fseek(tmpfile.fid,current-size*(channels+1)*8,'bof'); %ftell(tmpfile.fid) [data count] = fread(tmpfile.fid,[size,channels],'double'); %count data = reshape(data,[size,1,channels]); [pos count] = fread(tmpfile.fid,size,'double'); %count % ftell(tmpfile.fid) fseek(tmpfile.fid,current-size*(channels+1)*8,'bof'); a = set(a,'Data',{{data}},'Pos',{{pos}}); if ch(3) fclose(tmpfile.fid); delete('tmpfile.mirtoolbox'); end argin{i} = a; end elseif isa(a,'mirdesign') if isempty(a.stored) % The design parameters are transfered to the previous component % in the design process a.size = d.size; a.chunk = d.chunk; a.file = d.file; a.channel = d.channel; a.eval = 1; a.interchunk = d.interchunk; a.sampling = d.sampling; if isstruct(d.frame) && isfield(d.frame,'decomposition') ... && not(isempty(d.frame.decomposition)) a.chunkdecomposed = 1; else a.chunkdecomposed = d.chunkdecomposed; end if not(isempty(d.frame)) && ... not(strcmp(func2str(d.method),'mirframe')) a.frame = d.frame; end a.ready = 1; a.acrosschunks = d.acrosschunks; a.index = d.index; argin{i} = a; else % Variable already calculated tmp = get(d,'Struct'); if not(isempty(tmp)) for j = 1:length(a.stored) % (if modified, modify also mirframe) stored = a.stored{j}; if iscell(stored) if length(stored)>1 tmp = tmp{stored{1},stored{2}}; else tmp = tmp{stored{1}}; end else tmp = getfield(tmp,stored); end end if iscell(tmp) tmp = tmp{1}; end else mirerror('evaleach','THERE is a problem..'); end argin{i} = tmp; end end end if not(iscell(d.argin)) argin = argin{1}; end d.option.struct = get(d,'Struct'); if iscell(d.postoption) [y argin] = d.method(argin,d.option,d.postoption{:}); else [y argin] = d.method(argin,d.option,d.postoption); end d = set(d,'Argin',argin); if isa(d,'mirstruct') && not(isfield(d.frame,'dontchunk')) && isempty(get(d,'Chunk')) y = evalbranches(d,y); end function z = evalbranches(d,y) % For complex flowcharts, now that the first temporary variable (y) has been % computed, the dependent features (d) should be evaluated as well. branch = get(d,'Data'); for i = 1:length(branch) if isa(branch{i},'mirdesign') && get(branch{i},'NoChunk') == 1 % if the value is 2, it is OK. %mirerror('mireval','Flowchart badly designed: mirstruct should not be used if one or several final variables do not accept chunk decomposition.'); end end fields = get(d,'Fields'); z = struct; tmp = get(d,'Tmp'); for i = 1:length(branch) z.(fields{i}) = evalbranch(branch{i},tmp,y); end if get(d,'Stat') && isempty(get(d,'Chunk')) z = mirstat(z,'FileNames',0); end function b = evalbranch(b,d,y) % We need to evaluate the branch reaching the current node (b) from the parent % corresponding to the temporary variable (d), if iscell(b) mirerror('MIREVAL','Sorry, forked branching of temporary variable cannnot be evaluated in current version of MIRtoolbox.'); end if isstruct(b) % Subtrees are evaluated branch after branch. f = fields(b); for i = 1:length(f) b.(f{i}) = evalbranch(b.(f{i}),d,y); end return end if isequal(b,d) %% Does it happen ever?? b = y; return end if not(isa(b,'mirdesign')) mirerror('MIRSTRUCT','In the mirstruct object you defined, the final output should only depend on ''tmp'' variables, and should not therefore reuse the ''Design'' keyword.'); end v = get(b,'Stored'); if length(v)>1 && ischar(v{2}) % f = fields(d); for i = 1:length(f) if strcmpi(v{2},f) b = y; % OK, now the temporary variable has been found. % End of recursion. return end end end argin = evalbranch(get(b,'Argin'),d,y); % Recursion one parent up % The operation corresponding to the branch from the parent to the node % is finally evaluated. if iscell(b.postoption) b = b.method(argin,b.option,b.postoption{:}); else b = b.method(argin,b.option,b.postoption); end function res = isaverage(specif) res = isfield(specif,'combinechunk') && ... ((ischar(specif.combinechunk) && ... strcmpi(specif.combinechunk,'Average')) || ... (iscell(specif.combinechunk) && ... ischar(specif.combinechunk{1}) && ... strcmpi(specif.combinechunk{1},'Average'))); function d0 = callbeforechunk(d0,d,w,lsz) % If necessary, the chunk decomposition is performed a first time for % initialisation purposes. % Currently used only for miraudio(...,'Normal') if not(ischar(d)) && not(iscell(d)) specif = d.specif; CHUNKLIM = mirchunklim; nch = ceil(lsz/CHUNKLIM); if isfield(specif,'beforechunk') ... && ((isfield(d.option,specif.beforechunk{2}) ... && d.option.(specif.beforechunk{2})) ... || (isfield(d.postoption,specif.beforechunk{2}) ... && d.postoption.(specif.beforechunk{2})) ) if mirwaitbar h = waitbar(0,['Preparing ' func2str(d.method)]); else h = 0; end for i = 1:nch disp(['Chunk ',num2str(i),'/',num2str(nch),'...']) chbeg = CHUNKLIM*(i-1); chend = CHUNKLIM*i-1; d2 = set(d,'Size',d0.size,'File',d0.file,... 'Chunk',[chbeg+w(1) min(chend,lsz-1)+w(1)]); d2.method = specif.beforechunk{1}; d2.postoption = {chend-lsz}; d2.chunkdecomposed = 1; [tmp d] = evalnow(d2); d0 = set(d0,'AcrossChunks',tmp); if h waitbar(chend/lsz,h) end end if h close(h); end drawnow else d0 = callbeforechunk(d0,d.argin,w,lsz); end end function y = concatchunk(old,new,ascending) do = get(old,'Data'); dn = get(new,'Data'); fpo = get(old,'FramePos'); fpn = get(new,'FramePos'); if isa(old,'mirscalar') y = set(old,'Data',{{[do{1}{1},dn{1}{1}]}},... 'FramePos',{{[fpo{1}{1},fpn{1}{1}]}}); else to = get(old,'Pos'); tn = get(new,'Pos'); if ascending y = set(old,'Data',{{[do{1}{1};dn{1}{1}]}},... 'Pos',{{[to{1}{1};tn{1}{1}]}},... 'FramePos',{{[fpo{1}{1},fpn{1}{1}]}}); else y = set(old,'Data',{{[dn{1}{1};do{1}{1}]}},... 'Pos',{{[tn{1}{1};to{1}{1}]}},... 'FramePos',{{[fpo{1}{1},fpn{1}{1}]}}); end end function y = combinesegment(old,new) do = get(old,'Data'); to = get(old,'Pos'); fpo = get(old,'FramePos'); ppo = get(old,'PeakPos'); pppo = get(old,'PeakPrecisePos'); pvo = get(old,'PeakVal'); ppvo = get(old,'PeakPreciseVal'); pmo = get(old,'PeakMode'); apo = get(old,'AttackPos'); rpo = get(old,'ReleasePos'); tpo = get(old,'TrackPos'); tvo = get(old,'TrackVal'); dn = get(new,'Data'); tn = get(new,'Pos'); fpn = get(new,'FramePos'); ppn = get(new,'PeakPos'); pppn = get(new,'PeakPrecisePos'); pvn = get(new,'PeakVal'); ppvn = get(new,'PeakPreciseVal'); pmn = get(new,'PeakMode'); apn = get(new,'AttackPos'); rpn = get(new,'ReleasePos'); tpn = get(new,'TrackPos'); tvn = get(new,'TrackVal'); if not(isempty(do)) y = set(old,'Data',{{do{1}{:},dn{1}{:}}}); end y = set(old,'FramePos',{{fpo{1}{:},fpn{1}{:}}}); if not(isempty(to)) && size(do{1},2) == size(to{1},2) y = set(y,'Pos',{{to{1}{:},tn{1}{:}}}); end if not(isempty(ppo)) y = set(y,'PeakPos',{{ppo{1}{:},ppn{1}{:}}},... 'PeakVal',{{pvo{1}{:},pvn{1}{:}}},... 'PeakMode',{{pmo{1}{:},pmn{1}{:}}}); end if not(isempty(pppn)) y = set(y,'PeakPrecisePos',{[pppo{1},pppn{1}{1}]},... 'PeakPreciseVal',{[ppvo{1},ppvn{1}{1}]}); end if not(isempty(apn)) y = set(y,'AttackPos',{[apo{1},apn{1}{1}]}); end if not(isempty(rpn)) y = set(y,'ReleasePos',{[rpo{1},rpn{1}{1}]}); end if not(isempty(tpn)) y = set(y,'TrackPos',{[tpo{1},tpn{1}{1}]}); end if not(isempty(tvn)) y = set(y,'TrackVal',{[tvo{1},tvn{1}{1}]}); end if isa(old,'miremotion') deo = get(old,'DimData'); ceo = get(old,'ClassData'); den = get(new,'DimData'); cen = get(new,'ClassData'); afo = get(old,'ActivityFactors'); vfo = get(old,'ValenceFactors'); tfo = get(old,'TensionFactors'); hfo = get(old,'HappyFactors'); sfo = get(old,'SadFactors'); tdo = get(old,'TenderFactors'); ago = get(old,'AngerFactors'); ffo = get(old,'FearFactors'); afn = get(new,'ActivityFactors'); vfn = get(new,'ValenceFactors'); tfn = get(new,'TensionFactors'); hfn = get(new,'HappyFactors'); sfn = get(new,'SadFactors'); tdn = get(new,'TenderFactors'); agn = get(new,'AngerFactors'); ffn = get(new,'FearFactors'); y = set(y,'DimData',{[deo{1},den{1}{1}]},... 'ClassData',{[ceo{1},cen{1}{1}]},... 'ActivityFactors',{[afo{1},afn{1}{1}]},... 'ValenceFactors',{[vfo{1},vfn{1}{1}]},... 'TensionFactors',{[tfo{1},tfn{1}{1}]},... 'HappyFactors',{[hfo{1},hfn{1}{1}]},... 'SadFactors',{[sfo{1},sfn{1}{1}]},... 'TenderFactors',{[tdo{1},tdn{1}{1}]},... 'AngerFactors',{[ago{1},agn{1}{1}]},... 'FearFactors',{[ffo{1},ffn{1}{1}]}... ); end function y = sumchunk(old,new,order) %do = mirgetdata(old); %dn = mirgetdata(new); do = get(old,'Data'); do = do{1}{1}; dn = get(new,'Data'); dn = dn{1}{1}; y = set(old,'ChunkData',do+dn); function y = divideweightchunk(orig,length) d = get(orig,'Data'); if isempty(d) y = orig; else v = mircompute(@divideweight,d,length); y = set(orig,'Data',v); end function e = multweight(d,length) e = d*length; function e = divideweight(d,length) e = d/length;