Exemplo n.º 1
0
    def bench_fft1_time(self):
        from numpy.fft import fft as numpy_fft
        from scipy.fftpack import fft as scipy_fft
        print
        print '   1D Double Precision Fast Fourier Transform'
        print '================================================='
        print '      |   complex input    '
        print '-------------------------------------------------'
        print ' size |  recon  |  numpy  |  scipy  |'
        print '-------------------------------------------------'
        for size,repeat in [(100,7000),(1000,2000),
                            (256,10000),
                            (512,10000),
                            (1024,1000),
                            (2048,1000),
                            (2048*2,500),
                            (2048*4,500),
                            ]:
            print '%5s' % size,
            sys.stdout.flush()

            x = random(repeat, size).astype(cdouble) + \
                random(repeat, size).astype(cdouble)*1j
            tr0 = time.time()
            y = fft1(x, shift=False)
            trf = time.time()
            print '|%8.2f' % (trf-tr0),
            sys.stdout.flush()
            tn0 = time.time()
            ny = numpy_fft(x)
            tnf = time.time()
            assert_array_almost_equal(ny,y)
            print '|%8.2f' % (tnf-tn0),
            sys.stdout.flush()
            ts0 = time.time()
            sy = scipy_fft(x)
            tsf = time.time()
            assert_array_almost_equal(sy,y)
            print '|%8.2f' % (tsf-ts0),
            sys.stdout.flush()

            print ' (secs for %s calls)' % (repeat)
        sys.stdout.flush()
        
        print
        print '   1D Double Precision Fast Fourier Transform'
        print '================================================='
        print '      |   complex input shifted   '
        print '-------------------------------------------------'
        print ' size |  recon  |  numpy  |  scipy  |'
        print '-------------------------------------------------'
        for size,repeat in [(100,7000),(1000,2000),
                            (256,10000),
                            (512,10000),
                            (1024,1000),
                            (2048,1000),
                            (2048*2,500),
                            (2048*4,500),
                            ]:
            chk = checkerline(size).astype(double)
            print '%5s' % size,
            sys.stdout.flush()

            x = random(repeat, size).astype(cdouble) + \
                random(repeat, size).astype(cdouble)*1j
            tr0 = time.time()
            y = fft1(x, shift=True)
            trf = time.time()
            print '|%8.2f' % (trf-tr0),
            sys.stdout.flush()
            tn0 = time.time()
            ny = chk*numpy_fft(chk*x)
            tnf = time.time()
            assert_array_almost_equal(ny,y)
            print '|%8.2f' % (tnf-tn0),
            sys.stdout.flush()
            ts0 = time.time()
            sy = chk*scipy_fft(chk*x)
            tsf = time.time()
            assert_array_almost_equal(sy,y)
            print '|%8.2f' % (tsf-ts0),
            sys.stdout.flush()

            print ' (secs for %s calls)' % (repeat)
        sys.stdout.flush()

        print
        print '   1D Single Precision Fast Fourier Transform'
        print '================================================='
        print '      |   complex input    '
        print '-------------------------------------------------'
        print ' size |  recon  |  numpy  |  scipy*  |'
        print '-------------------------------------------------'
        for size,repeat in [(100,7000),(1000,2000),
                            (256,10000),
                            (512,10000),
                            (1024,1000),
                            (2048,1000),
                            (2048*2,500),
                            (2048*4,500),
                            ]:
            print '%5s' % size,
            sys.stdout.flush()

            x = random(repeat, size).astype(csingle) + \
                random(repeat, size).astype(csingle)*1j
            tr0 = time.time()
            y = fft1(x, shift=False)
            trf = time.time()
            print '|%8.2f' % (trf-tr0),
            sys.stdout.flush()
            tn0 = time.time()
            ny = numpy_fft(x)
            tnf = time.time()
            assert_array_almost_equal(ny,y, decimal=2)
            print '|%8.2f' % (tnf-tn0),
            sys.stdout.flush()
            ts0 = time.time()
            sy = scipy_fft(x.astype(cdouble)).astype(csingle)
            tsf = time.time()
            assert_array_almost_equal(sy,y, decimal=2)
            print '|%8.2f' % (tsf-ts0),
            sys.stdout.flush()

            print ' (secs for %s calls)' % (repeat)
        print "(* casted float->FT{double}->float)"

        sys.stdout.flush()
        print
        print '   1D Single Precision Fast Fourier Transform'
        print '================================================='
        print '      |   complex input shifted   '
        print '-------------------------------------------------'
        print ' size |  recon  |  numpy  |  scipy*  |'
        print '-------------------------------------------------'
        for size,repeat in [(100,7000),(1000,2000),
                            (256,10000),
                            (512,10000),
                            (1024,1000),
                            (2048,1000),
                            (2048*2,500),
                            (2048*4,500),
                            ]:
            chk = checkerline(size).astype(single)
            print '%5s' % size,
            sys.stdout.flush()

            x = random(repeat, size).astype(csingle) + \
                random(repeat, size).astype(csingle)*1j
            tr0 = time.time()
            y = fft1(x, shift=True)
            trf = time.time()
            print '|%8.2f' % (trf-tr0),
            sys.stdout.flush()
            tn0 = time.time()
            ny = chk*numpy_fft(chk*x)
            tnf = time.time()
            assert_array_almost_equal(ny,y, decimal=2)
            print '|%8.2f' % (tnf-tn0),
            sys.stdout.flush()
            ts0 = time.time()
            sy = chk*(scipy_fft((chk*x).astype(cdouble))).astype(csingle)
            tsf = time.time()
            assert_array_almost_equal(sy,y, decimal=2)
            print '|%8.2f' % (tsf-ts0),
            sys.stdout.flush()

            print ' (secs for %s calls)' % (repeat)
        print "(* casted float->FT{double}->float)"
        sys.stdout.flush()
Exemplo n.º 2
0
    b_out = CopyBlock(b_fft, space='system', core=3)
    b_write = BinaryFileWriteBlock(b_out, core=4)

    # Run pipeline
    pipeline = bfp.get_default_pipeline()
    print(pipeline.dot_graph())
    pipeline.run()

    # Check the output files match the input files
    for filename in filenames:
        try:
            print(filename)

            # Load the input data, do a windowed FFT
            indata = np.fromfile(filename, dtype='complex64')
            indata = scipy_fft(indata.reshape(n_window, window_len), axis=1)

            # Load the output data and reshape into windowed FFTs
            outdata = np.fromfile('%s.out' % filename, dtype='complex64')
            outdata = outdata.reshape(n_window, window_len)

            assert np.allclose(indata, outdata, atol=0.1)
            print("    Input data and output data match.")
        except AssertionError:
            print("    Error: input and output data do not match.")
            for ii in range(len(indata)):
                print("Window %02i match: %s" %
                      (ii, np.allclose(indata[ii], outdata[ii], atol=0.1)))
            print(indata[0, 0:10])
            print(outdata[0, 0:10])
            print(np.max(indata - outdata))
Exemplo n.º 3
0
def bench_fft1_time():
    from numpy.fft import fft as numpy_fft
    from scipy.fftpack import fft as scipy_fft
    print
    print '   1D Double Precision Fast Fourier Transform'
    print '================================================='
    print '      |   complex input    '
    print '-------------------------------------------------'
    print ' size |  fftw  |  numpy  |  scipy  |'
    print '-------------------------------------------------'
    for size, repeat in [
        (100, 7000),
        (1000, 2000),
        (256, 10000),
        (512, 10000),
        (1024, 1000),
        (2048, 1000),
        (2048 * 2, 500),
        (2048 * 4, 500),
    ]:
        print '%5s' % size,
        sys.stdout.flush()

        x = random(repeat, size).astype('D') + \
            random(repeat, size).astype('D')*1j
        tr0 = time.time()
        y = fft1(x, shift=False)
        trf = time.time()
        print '|%8.2f' % (trf - tr0),
        sys.stdout.flush()
        tn0 = time.time()
        ny = numpy_fft(x)
        tnf = time.time()
        ##         assert_array_almost_equal(ny,y)
        print '|%8.2f' % (tnf - tn0),
        sys.stdout.flush()
        ts0 = time.time()
        sy = scipy_fft(x)
        tsf = time.time()
        ##         assert_array_almost_equal(sy,y)
        print '|%8.2f' % (tsf - ts0),
        sys.stdout.flush()

        print ' (secs for %s calls)' % (repeat)
    sys.stdout.flush()

    print
    print '   1D Double Precision Fast Fourier Transform'
    print '================================================='
    print '      |   complex input shifted   '
    print '-------------------------------------------------'
    print ' size |  fftw  |  numpy  |  scipy  |'
    print '-------------------------------------------------'
    for size, repeat in [
        (100, 7000),
        (1000, 2000),
        (256, 10000),
        (512, 10000),
        (1024, 1000),
        (2048, 1000),
        (2048 * 2, 500),
        (2048 * 4, 500),
    ]:
        chk = checkerline(size).astype('d')
        print '%5s' % size,
        sys.stdout.flush()

        x = random(repeat, size).astype('D') + \
            random(repeat, size).astype('D')*1j
        tr0 = time.time()
        y = fft1(x, shift=True)
        trf = time.time()
        print '|%8.2f' % (trf - tr0),
        sys.stdout.flush()
        tn0 = time.time()
        ny = chk * numpy_fft(chk * x)
        tnf = time.time()
        ##         assert_array_almost_equal(ny,y)
        print '|%8.2f' % (tnf - tn0),
        sys.stdout.flush()
        ts0 = time.time()
        sy = chk * scipy_fft(chk * x)
        tsf = time.time()
        ##         assert_array_almost_equal(sy,y)
        print '|%8.2f' % (tsf - ts0),
        sys.stdout.flush()

        print ' (secs for %s calls)' % (repeat)
    sys.stdout.flush()

    print
    print '   1D Single Precision Fast Fourier Transform'
    print '================================================='
    print '      |   complex input    '
    print '-------------------------------------------------'
    print ' size |  fftw  |  numpy  |  scipy*  |'
    print '-------------------------------------------------'
    for size, repeat in [
        (100, 7000),
        (1000, 2000),
        (256, 10000),
        (512, 10000),
        (1024, 1000),
        (2048, 1000),
        (2048 * 2, 500),
        (2048 * 4, 500),
    ]:
        print '%5s' % size,
        sys.stdout.flush()

        x = random(repeat, size).astype('F') + \
            random(repeat, size).astype('F')*1j
        tr0 = time.time()
        y = fft1(x, shift=False)
        trf = time.time()
        print '|%8.2f' % (trf - tr0),
        sys.stdout.flush()
        tn0 = time.time()
        ny = numpy_fft(x)
        tnf = time.time()
        ##         assert_array_almost_equal(ny,y, decimal=2)
        print '|%8.2f' % (tnf - tn0),
        sys.stdout.flush()
        ts0 = time.time()
        sy = scipy_fft(x.astype('D')).astype('F')
        tsf = time.time()
        ##         assert_array_almost_equal(sy,y, decimal=2)
        print '|%8.2f' % (tsf - ts0),
        sys.stdout.flush()

        print ' (secs for %s calls)' % (repeat)
    print "(* casted float->FT{double}->float)"

    sys.stdout.flush()
    print
    print '   1D Single Precision Fast Fourier Transform'
    print '================================================='
    print '      |   complex input shifted   '
    print '-------------------------------------------------'
    print ' size |  fftw  |  numpy  |  scipy*  |'
    print '-------------------------------------------------'
    for size, repeat in [
        (100, 7000),
        (1000, 2000),
        (256, 10000),
        (512, 10000),
        (1024, 1000),
        (2048, 1000),
        (2048 * 2, 500),
        (2048 * 4, 500),
    ]:
        chk = checkerline(size).astype('f')
        print '%5s' % size,
        sys.stdout.flush()

        x = random(repeat, size).astype('F') + \
            random(repeat, size).astype('F')*1j
        tr0 = time.time()
        y = fft1(x, shift=True)
        trf = time.time()
        print '|%8.2f' % (trf - tr0),
        sys.stdout.flush()
        tn0 = time.time()
        ny = chk * numpy_fft(chk * x)
        tnf = time.time()
        ##         assert_array_almost_equal(ny,y, decimal=2)
        print '|%8.2f' % (tnf - tn0),
        sys.stdout.flush()
        ts0 = time.time()
        sy = chk * (scipy_fft((chk * x).astype('D'))).astype('F')
        tsf = time.time()
        ##         assert_array_almost_equal(sy,y, decimal=2)
        print '|%8.2f' % (tsf - ts0),
        sys.stdout.flush()

        print ' (secs for %s calls)' % (repeat)
    print "(* casted float->FT{double}->float)"
    sys.stdout.flush()
    assert True, 'WTF!'