comparison toolboxes/bioakustik_tools/sp/seq_wavwrite.m @ 0:e9a9cd732c1e tip

first hg version after svn
author wolffd
date Tue, 10 Feb 2015 15:05:51 +0000
parents
children
comparison
equal deleted inserted replaced
-1:000000000000 0:e9a9cd732c1e
1 function seq_wavwrite(in_files,wavefile,varargin)
2 % Combines wav-data from folder or specific files in one file.
3 %
4 % seq_wavwrite(path_string,wavefile) combines all .wav files in
5 % path_string in the file wavefile.
6 % i.e.: seq_wavwrite('C:\wav\','C:\combined.wav')
7 %
8 % The file format will depend on the first file processed, the other
9 % files will be transfered to this format by resampling, dithering and
10 % channel repetition/rejection. You may use some of the extra-options 'Fs','nbits'
11 % or 'channels' to override these settings.
12 % i.e.: seq_wavwrite('C:\wav\','C:\combined.wav','Fs',44100,'nbits',16,'channels',1)
13 % will produce a mono file with 44.1 kHz samle rate and 16bits per sample
14 %
15 % seq_wavwrite(files_cellarray,wavefile) only combines the files specified
16 % in files_cellarray.
17 % i.e.: files={'C:\wav\test1.wav','C:\other_wav\test2.wav'};
18 % seq_wavwrite(files,'C:\combined.wav');
19 %
20 % You may want to copy only some parts of the files.
21 % Therefore use the extra-option 'sequences':
22 % seq_wavwrite(files,'C:\combined','sequences',segments);
23 % ,where segments is an cell array the same size as the files_cellarray,
24 % witch contains the position of the parts for every file.
25 % Every cell row contains a struct array with the following fields:
26 % abs_startspl and abs_stopspl
27 % or
28 % abs_startms and abs_stopms
29 % You may also specify the channels that are to be copied in the field
30 % channels
31 % i.e.: files={'C:\wav\test1.wav','C:\other_wav\test2.wav'};
32 % segsforfile1(1).abs_startspl=1;
33 % segsforfile1(1).abs_stopspl=44100;
34 % segsforfile1(2).abs_startspl=88200;
35 % segsforfile1(2).abs_stopspl=200000;
36 % segsforfile2(1).abs_startms=1;
37 % segsforfile2(1).abs_stopms=2000;
38 % segsforfile2(1).channels=[1 2]; <- use the first two channels
39 % segments={segsforfile1,segsforfile2};
40 % seq_wavwrite(files,'C:\combined','sequences',segments);
41 %
42 % If you want to copy specific files as a whole, just omit their abs_...
43 % values.
44 %
45 % seq_wavwrite uses blockwise file processing to be able to copy large
46 % amounts of data. The option 'max_chunksize' allows you to specify the
47 % blocksize in samples. Keep in mind that in multichannel mode the actual
48 % blocksize will be chunksize times channels.
49 % i.e.: seq_wavwrite('C:\wav\','C:\combined.wav','max_chunksize',44100*60)
50
51 % Parse inputs:
52
53 [slash,leftargs]=process_options(varargin,'systemslash','\');
54
55 if ischar(in_files)
56 data_names=dir(strcat(in_files,slash,'*.wav'));
57 in_files=strcat(in_files,{data_names.name});
58 end
59
60 [tmp_sig,tmp_Fs,tmp_nbits]=wavread(char(in_files{1}),[1 2]);
61 tmp_channels=size(tmp_sig,2);
62
63 def_max_chunk_size = 44100*60*2;%chunksize nearly one minute at 44,1 khz sample rate
64 [sequences,Fs,nbits,channels,max_chunk_size]=process_options(leftargs,'sequences',[],'Fs',...
65 tmp_Fs,'nbits',tmp_nbits,'channels',tmp_channels,'max_chunksize',def_max_chunk_size);
66
67 if ischar(in_files) && ~isempty(sequences)
68 warning('segment parameters ignored in directory-input mode')
69 sequences=[];
70 end
71
72 % Determine number of bytes in chunks
73 % (not including pad bytes, if needed):
74 % ----------------------------------
75 % 'RIFF' 4 bytes
76 % size 4 bytes
77 % 'WAVE' 4 bytes
78 % 'fmt ' 4 bytes
79 % size 4 bytes
80 % <wave-format> 14 bytes
81 % <format_specific> 2 bytes (PCM)
82 % 'data' 4 bytes
83 % size 4 bytes
84 % <wave-data> N bytes
85 % ----------------------------------
86
87 bytes_per_sample = ceil(nbits/8);
88 fmt_cksize = 16; % Don't include 'fmt ' or its size field
89
90 % Open file for output:
91 [fid,err] = OpenWaveWrite(wavefile);
92 error(err);
93 try
94 % Prepare basic chunk structure fields:
95 ck=[]; ck.fid=fid; ck.filename = wavefile;
96
97 fwrite(fid,zeros(1,20),'uchar'); %skip previous chunks
98 % Write <wave-format>:
99 fmt.filename = wavefile;
100 if nbits == 32,
101 fmt.wFormatTag = 3; % Data encoding format (1=PCM, 3=Type 3 32-bit)
102 else
103 fmt.wFormatTag = 1;
104 end
105 fmt.nSamplesPerSec = Fs; % Samples per second
106 fmt.nAvgBytesPerSec = channels*bytes_per_sample*Fs; % Avg transfer rate
107 fmt.nBlockAlign = channels*bytes_per_sample; % Block alignment
108 fmt.nBitsPerSample = nbits; % standard <PCM-format-specific> info
109 fmt.nChannels = channels; % Number of channels
110 error(write_wavefmt(fid,fmt));
111
112 fwrite(fid,zeros(1,8),'uchar'); %skip following chunks
113
114 % Write all audio data
115 sample_sum=0;
116 for filei=1:size(in_files,2)
117 resamplewarn=0;
118 channelwarn=0;
119 if ~isempty(sequences)&& ~isempty(sequences{filei})
120 numsegs=size(sequences{filei},2);
121 else numsegs=1;
122 end
123 for seqi=1:numsegs;
124 tmp_fsiz=wavread(char(in_files{filei}),'size');
125 tmp_fsiz=tmp_fsiz(1);
126 [y,tmp_fs,null]=wavread(char(in_files{filei}),[1 2]);%read data
127 if ~isempty(sequences) && ~isempty(sequences{filei})
128 if isfield(sequences{filei}(seqi),'abs_startspl')
129 spl_seq=[sequences{filei}(seqi).abs_startspl sequences{filei}(seqi).abs_stopspl];
130 elseif isfield(sequences{filei}(seqi),'abs_startms')
131 spl_seq=floor([sequences{filei}(seqi).abs_startms sequences{filei}(seqi).abs_stopms].*tmp_fs./1000);
132 else
133 spl_seq=[1 tmp_fsiz];
134 end
135 if (spl_seq(1)< 1) || (spl_seq(2) > tmp_fsiz)
136 warning('correcting segment range, not necessary critical in miliseconds-mode')
137 spl_seq(1)=max(spl_seq(1),1);
138 spl_seq(2)=min(spl_seq(2),tmp_fsiz);
139 end
140 else
141 spl_seq=[1 tmp_fsiz];
142 end
143 win_start=spl_seq(1);
144 win_stop=(min(spl_seq(2),spl_seq(1)+max_chunk_size-1));
145 while win_stop <= spl_seq(2)
146 [y,tmp_fs,null]=wavread(char(in_files{filei}),[win_start win_stop]);%read data
147 if (size(y,2) > 1) && ~isempty(sequences) && isfield(sequences{filei}(seqi),'channels') %choose channel
148 if size(y,2) >= max(sequences{filei}(seqi).channels)
149 y=y(:,sequences{filei}(seqi).channels);
150 else
151 if ~channelwarn
152 warning('ignoring errorneous channel field');
153 channelwarn=1;
154 end
155 end
156 end
157 if (tmp_fs ~= Fs) %resample data if necessary
158 if ~resamplewarn
159 fprintf('seq_wavwrite.m: resampling from %d to %d Hz. \n',tmp_fs,Fs);
160 resamplewarn=1;
161 end
162 y=resample(y,Fs,tmp_fs);
163 end
164 [samples,akt_channels] = size(y);
165 if akt_channels > channels % if necessary make equivalent channelnum
166 y=y(:,1:channels);
167 elseif akt_channels < channels
168 y=[y repmat(y(:,end),1,channels-akt_channels)];
169 end
170 error(write_wavedat(fid,fmt,y));
171 sample_sum=sample_sum+samples;
172
173 if win_stop == spl_seq(2), break;
174 end
175 win_start=win_start+max_chunk_size;
176 win_stop=(min(spl_seq(2),win_stop+max_chunk_size));
177 end
178 end
179 end
180 clear y;
181
182 total_samples = sample_sum * channels;
183 total_bytes = total_samples * bytes_per_sample;
184 data_cksize = total_bytes;
185
186 riff_cksize = 36+total_bytes;
187
188 % Determine pad bytes:
189 % Determine if a pad-byte must be appended to data chunk:
190 if rem(data_cksize, 2) ~= 0,
191 fwrite(fid,0,'uchar');
192 end
193 data_pad = rem(data_cksize,2);
194 riff_cksize = riff_cksize + data_pad; % + fmt_pad, always 0
195
196 % Write RIFF chunk:
197 fseek(fid,0,'bof');
198 ck.ID = 'RIFF';
199 ck.Size = riff_cksize;
200 error(write_ckinfo(ck));
201
202 % Write WAVE subchunk:
203 ck.ID = 'WAVE';
204 ck.Size = []; % Indicate a subchunk (no chunk size)
205 error(write_ckinfo(ck));
206
207 % Write <fmt-ck>:
208 ck.ID = 'fmt ';
209 ck.Size = fmt_cksize;
210 error(write_ckinfo(ck));
211
212 % Write <data-ck>:
213 fseek(fid,36,'bof');
214 ck.ID = 'data';
215 ck.Size = data_cksize;
216 error(write_ckinfo(ck));
217 err='';
218 catch
219 err=lasterr;
220 end
221 % Close file:
222 fclose(fid);
223
224 error(err);
225 % end of wavwrite()
226
227
228 % ------------------------------------------------------------------------
229 % Private functions:
230 % ------------------------------------------------------------------------
231
232
233 % ------------------------------------------------------------------------
234 function [fid,err] = OpenWaveWrite(wavefile)
235 % OpenWaveWrite
236 % Open WAV file for writing.
237 % If filename does not contain an extension, add ".wav"
238
239 fid = [];
240 err = '';
241 if ~isstr(wavefile),
242 err='Wave file name must be a string.'; return;
243 end
244 if isempty(findstr(wavefile,'.')),
245 wavefile=[wavefile '.wav'];
246 end
247 % Open file, little-endian:
248 [fid,err] = fopen(wavefile,'wb','l');
249
250 return
251
252
253 % ------------------------------------------------------------------------
254 function err = write_ckinfo(ck)
255 % WRITE_CKINFO: Writes next RIFF chunk, but not the chunk data.
256 % Assumes the following fields in ck:
257 % .fid File ID to an open file
258 % .ID 4-character string chunk identifier
259 % .Size Size of chunk (empty if subchunk)
260 %
261 %
262 % Expects an open FID pointing to first byte of chunk header,
263 % and a chunk structure.
264 % ck.fid, ck.ID, ck.Size, ck.Data
265
266 errmsg = ['Failed to write ' ck.ID ' chunk to WAVE file: ' ck.filename];
267 err = '';
268
269 if (fwrite(ck.fid, ck.ID, 'char') ~= 4),
270 err=errmsg; return;
271 end
272
273 if ~isempty(ck.Size),
274 % Write chunk size:
275 if (fwrite(ck.fid, ck.Size, 'uint32') ~= 1),
276 err=errmsg; return;
277 end
278 end
279
280 return
281
282 % ------------------------------------------------------------------------
283 function err = write_wavefmt(fid, fmt)
284 % WRITE_WAVEFMT: Write WAVE format chunk.
285 % Assumes fid points to the wave-format subchunk.
286 % Requires chunk structure to be passed, indicating
287 % the length of the chunk.
288
289 errmsg = ['Failed to write WAVE format chunk to file' fmt.filename];
290 err = '';
291
292 % Create <wave-format> data:
293 if (fwrite(fid, fmt.wFormatTag, 'uint16') ~= 1) | ...
294 (fwrite(fid, fmt.nChannels, 'uint16') ~= 1) | ...
295 (fwrite(fid, fmt.nSamplesPerSec, 'uint32' ) ~= 1) | ...
296 (fwrite(fid, fmt.nAvgBytesPerSec, 'uint32' ) ~= 1) | ...
297 (fwrite(fid, fmt.nBlockAlign, 'uint16') ~= 1),
298 err=errmsg; return;
299 end
300
301 % Write format-specific info:
302 if fmt.wFormatTag==1 | fmt.wFormatTag==3,
303 % Write standard <PCM-format-specific> info:
304 if (fwrite(fid, fmt.nBitsPerSample, 'uint16') ~= 1),
305 err=errmsg; return;
306 end
307
308 else
309 err='Unknown data format.';
310 end
311
312 return
313
314
315 % -----------------------------------------------------------------------
316 function y = PCM_Quantize(x, fmt)
317 % PCM_Quantize:
318 % Scale and quantize input data, from [-1, +1] range to
319 % either an 8-, 16-, or 24-bit data range.
320
321 % Clip data to normalized range [-1,+1]:
322 ClipMsg = ['Data clipped during write to file:' fmt.filename];
323 ClipWarn = 0;
324
325 % Determine slope (m) and bias (b) for data scaling:
326 nbits = fmt.nBitsPerSample;
327 m = 2.^(nbits-1);
328
329 switch nbits
330 case 8,
331 b=128;
332 case {16,24},
333 b=0;
334 otherwise,
335 error('Invalid number of bits specified.');
336 end
337
338 y = round(m .* x + b);
339
340 % Determine quantized data limits, based on the
341 % presumed input data limits of [-1, +1]:
342 ylim = [-1 +1];
343 qlim = m * ylim + b;
344 qlim(2) = qlim(2)-1;
345
346 % Clip data to quantizer limits:
347 i = find(y < qlim(1));
348 if ~isempty(i),
349 warning(ClipMsg); ClipWarn=1;
350 y(i) = qlim(1);
351 end
352
353 i = find(y > qlim(2));
354 if ~isempty(i),
355 if ~ClipWarn, warning(ClipMsg); end
356 y(i) = qlim(2);
357 end
358
359 return
360
361
362 % -----------------------------------------------------------------------
363 function err = write_wavedat(fid,fmt,data)
364 % WRITE_WAVEDAT: Write WAVE data chunk
365 % Assumes fid points to the wave-data chunk
366 % Requires <wave-format> structure to be passed.
367
368 err = '';
369
370 if fmt.wFormatTag==1 | fmt.wFormatTag==3,
371 % PCM Format
372
373 % 32-bit Type 3 is normalized, so no scaling needed.
374 if fmt.nBitsPerSample ~= 32,
375 data = PCM_Quantize(data, fmt);
376 end
377
378 switch fmt.nBitsPerSample
379 case 8,
380 dtype='uchar'; % unsigned 8-bit
381 case 16,
382 dtype='int16'; % signed 16-bit
383 case 24,
384 dtype='bit24'; % signed 24-bit
385 case 32,
386 dtype='float'; % normalized 32-bit floating point
387 otherwise,
388 err = 'Invalid number of bits specified.'; return;
389 end
390
391 % Write data, one row at a time (one sample from each channel):
392 [samples,channels] = size(data);
393 total_samples = samples*channels;
394
395 if (fwrite(fid, reshape(data',total_samples,1), dtype) ~= total_samples),
396 err = 'Failed to write PCM data samples.'; return;
397 end
398
399
400 else
401 % Unknown wave-format for data.
402 err = 'Unsupported data format.';
403 end
404
405 return
406
407 % end of wavwrite.m