from numpy.testing import TestCase, run_module_suite from numpy.testing import assert_equal, assert_almost_equal from aubio import fvec from _aubio import * from numpy import array, shape class aubio_pvoc_test_case(TestCase): def test_members(self): f = pvoc() assert_equal ([f.win_s, f.hop_s], [1024, 512]) f = pvoc(2048, 128) assert_equal ([f.win_s, f.hop_s], [2048, 128]) def test_zeros(self): win_s, hop_s = 1024, 256 f = pvoc (win_s, hop_s) t = fvec (hop_s) for time in range( 4 * win_s / hop_s ): s = f(t) r = f.rdo(s) assert_equal ( array(t), 0) assert_equal ( s.norm, 0) assert_equal ( s.phas, 0) assert_equal ( r, 0) def test_steps_two_channels(self): """ check the resynthesis of steps is correct """ f = pvoc(1024, 512) t1 = fvec(512) t2 = fvec(512) # positive step in first channel t1[100:200] = .1 # positive step in second channel t1[20:50] = -.1 s1 = f(t1) r1 = f.rdo(s1) s2 = f(t2) r2 = f.rdo(s2) #self.plot_this ( s1.norm.T ) assert_almost_equal ( t1, r2, decimal = 6 ) def test_steps_three_random_channels(self): from random import random f = pvoc(64, 16) t0 = fvec(16) t1 = fvec(16) for i in xrange(16): t1[i] = random() * 2. - 1. t2 = f.rdo(f(t1)) t2 = f.rdo(f(t0)) t2 = f.rdo(f(t0)) t2 = f.rdo(f(t0)) assert_almost_equal( t1, t2, decimal = 6 ) def plot_this( self, this ): from pylab import semilogy, show semilogy ( this ) show () if __name__ == '__main__': from unittest import main main()