sndwarpst — Reads a stereo sound sample from a table and applies time-stretching and/or pitch modification.
sndwarpst reads stereo sound samples from a table and applies time-stretching and/or pitch modification. Time and frequency modification are independent from one another. For example, a sound can be stretched in time while raising the pitch!
The window size and overlap arguments are important to the result and should be experimented with. In general they should be as small as possible. For example, start with iwsize=sr/10 and ioverlap=15. Try irandw=iwsize*.2. If you can get away with less overlaps, the program will be faster. But too few may cause an audible flutter in the amplitude. The algorithm reacts differently depending upon the input sound and there are no fixed rules for the best use in all circumstances. But with proper tuning, excellent results can be achieved.
ar1, ar2 [,ac1] [, ac2] sndwarpst xamp, xtimewarp, xresample, ifn1, \
ibeg, iwsize, irandw, ioverlap, ifn2, itimemode
ifn1 -- the number of the table holding the sound samples which will be subjected to the sndwarpst processing. GEN01 is the appropriate function generator to use to store the sound samples from a pre-existing soundfile.
ibeg -- the time in seconds to begin reading in the table (or soundfile). When itimemode is non-zero, the value of xtimewarp is offset by ibeg.
iwsize -- the window size in samples used in the time scaling algorithm.
irandw -- the bandwidth of a random number generator. The random numbers will be added to iwsize.
ioverlap -- determines the density of overlapping windows.
ifn2 -- a function used to shape the window. It is usually used to create a ramp of some kind from zero at the beginning and back down to zero at the end of each window. Try using a half a sine (i.e.: f1 0 16384 9 .5 1 0) which works quite well. Other shapes can also be used.
ar1, ar2 -- ar1 and ar2 are the stereo (left and right) outputs from sndwarpst. sndwarpst assumes that the function table holding the sampled signal is a stereo one. sndwarpst will index the table by a two-sample frame increment. The user must be aware then that if a mono signal is used with sndwarpst, time and pitch will be altered accordingly.
ac1, ac2 -- ac1 and ac2 are single-layer (no overlaps), unwindowed versions of the time and/or pitch altered signal. They are supplied in order to be able to balance the amplitude of the signal output, which typically contains many overlapping and windowed versions of the signal, with a clean version of the time-scaled and pitch-shifted signal. The sndwarpst process can cause noticeable changes in amplitude, (up and down), due to a time differential between the overlaps when time-shifting is being done. When used with a balance unit, ac1 and ac2 can greatly enhance the quality of sound. They are optional, but note that they must both be present in the syntax (use both or neither). An example of how to use this is given below.
xamp -- the value by which to scale the amplitude (see note on the use of this when using ac1 and ac2).
xtimewarp -- determines how the input signal will be stretched or shrunk in time. There are two ways to use this argument depending upon the value given for itimemode. When the value of itimemode is 0, xtimewarp will scale the time of the sound. For example, a value of 2 will stretch the sound by 2 times. When itimemode is any non-zero value then xtimewarp is used as a time pointer in a similar way in which the time pointer works in lpread and pvoc. An example below illustrates this. In both cases, the pitch will not be altered by this process. Pitch shifting is done independently using xresample.
xresample -- the factor by which to change the pitch of the sound. For example, a value of 2 will produce a sound one octave higher than the original. The timing of the sound, however, will not be altered.
Here is an example of the sndwarpst opcode. It uses the file sndwarpst.csd.
Example 986. Example of the sndwarpst opcode.
See the sections Real-time Audio and Command Line Flags for more information on using command line flags.
<CsoundSynthesizer> <CsOptions> ; Select audio/midi flags here according to platform -odac ;;;realtime audio out ;-iadc ;;;uncomment -iadc if realtime audio input is needed too ; For Non-realtime ouput leave only the line below: ; -o sndwarpst.wav -W ;;; for file output any platform </CsOptions> <CsInstruments> ; by Menno Knevel 2022 sr = 44100 ksmps = 32 nchnls = 2 0dbfs = 1 instr 1 ktimewarp line 0, p3, 1 ;length of stereo file "drumsSlp.wav" kresample init 1 ;playback at the normal speed ibeg = 0 iwsize = 4410 irandw = 441 ioverlap = p4 itimemode = 1 ; Use the ktimewarp parameter as a "time" pointer prints "\nnumber of overlaps = %d\n\n", p4 aL, aR sndwarpst .35, ktimewarp, kresample, 1, ibeg, iwsize, irandw, ioverlap, 2, itimemode aL dcblock aL ;get rid of DC offsets for left channel & aR dcblock aR ;right channel outs aL, aR endin </CsInstruments> <CsScore> f 1 0 0 1 "drumsSlp.wav" 0 0 0 f 2 0 16384 9 0.5 1 0 ;half of a sine wave i 1 0 7 2 ;different overlaps i 1 + 7 5 i 1 + 7 15 e </CsScore> </CsoundSynthesizer>
The below example shows a slowing down or stretching of the sound stored in the stored table (ifn1). Over the duration of the note, the stretching will grow from no change from the original to a sound which is ten times “slower” than the original. At the same time the overall pitch will move upward over the duration by an octave.
iwindfun = 1 isampfun = 2 ibeg = 0 iwindsize = 2000 iwindrand = 400 ioverlap = 10 awarp line 1, p3, 1 aresamp line 1, p3, 2 kenv line 1, p3, .1 asig sndwarp kenv, awarp, aresamp, isampfun, ibeg, iwindsize, iwindrand, ioverlap, iwindfun, 0
Now, here is an example using xtimewarp as a time pointer and using stereo:
itimemode = 1 atime line 0, p3, 10 ar1, ar2 sndwarpst kenv, atime, aresamp, sampfun, ibeg, iwindsize, iwindrand, ioverlap, \ iwindfun, itimemode
In the above, atime advances the time pointer used in the sndwarpst from 0 to 10 over the duration of the note. If p3 is 20 then the sound will be two times slower than the original. Of course you can use a more complex function than just a single straight line to control the time factor.
Now the same as above but using the balance function with the optional outputs:
asig,acmp sndwarp 1, awarp, aresamp, isampfun, ibeg, iwindsize, iwindrand, ioverlap, iwindfun, itimemode abal balance asig, acmp asig1,asig2,acmp1,acmp2 sndwarpst 1, atime, aresamp, sampfun, ibeg, iwindsize, iwindrand, ioverlap, \ iwindfun, itimemode abal1 balance asig1, acmp1 abal2 balance asig2, acmp2
In the above two examples notice the use of the balance unit. The output of balance can then be scaled, enveloped, sent to an out or outs, and so on. Notice that the amplitude arguments to sndwarp and sndwarpst are “1” in these examples. By scaling the signal after the sndwarp process, abal, abal1, and abal2 should contain signals that have nearly the same amplitude as the original input signal to the sndwarp process. This makes it much easier to predict the levels and avoid samples out of range or sample values that are too small.
More Advice | |
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Only use the stereo version when you really need to be processing a stereo file. It is somewhat slower than the mono version and if you use the balance function it is slower again. There is nothing wrong with using a mono sndwarp in a stereo orchestra and sending the result to one or both channels of the stereo output! |