def test_uniform_discrete(rnd, l, r):
# uniform discrete random variate generator
uniformdiscrete_dist = RVGs.UniformDiscrete(l, r)
# obtain samples
samples = get_samples(uniformdiscrete_dist, rnd)
# report mean and variance
print_test_results('Uniform Discrete',
samples,
expectation=(l + r) / 2.0,
variance=((r - l + 1)**2 - 1) / 12.0)
print("Fitting Normal:", dictResults)
# 14 Triangular
dist = RVGs.Triangular(0.5, loc=1, scale=2)
dat_tri = np.array(get_samples(dist, np.random))
dictResults = Fit.fit_triang(dat_tri, 'Data', fixed_location=1) # fit
print("Fitting Triangular:", dictResults)
# 15 Uniform
dist = RVGs.Uniform(0, 1)
dat_unif = np.array(get_samples(dist, np.random)) # mean, sigma
dictResults = Fit.fit_uniform(dat_unif, 'Data') # fit
print("Fitting Uniform:", dictResults)
# 16 UniformDiscrete
dist = RVGs.UniformDiscrete(0, 100)
dat_unifDis = np.array(get_samples(dist, np.random))
dictResults = Fit.fit_uniformDiscrete(dat_unifDis, 'Data') # fit
print("Fitting UniformDiscrete:", dictResults)
# 17 fitting a Weibull distribution
dist = RVGs.Weibull(5, 1, 2)
dat_weibull = np.array(get_samples(dist, np.random)) # generate data
dictResults = Fit.fit_weibull(dat_weibull, 'Data', fixed_location=1) # fit
print("Fitting Weibull:", dictResults)
# 18 fitting a Poisson distribution
dist = RVGs.Poisson(30, 1)
dat_poisson = np.array(get_samples(dist, np.random)) # generate data
dictResults = Fit.fit_poisson(dat_poisson, 'Data', fixed_location=1) # fit
print("Fitting Poisson:", dictResults)
