import numpy as np from collections import namedtuple from scipy import special from scipy import stats from scipy.stats._stats_py import _rankdata from ._axis_nan_policy import _axis_nan_policy_factory def _broadcast_concatenate(x, y, axis): '''Broadcast then concatenate arrays, leaving concatenation axis last''' x = np.moveaxis(x, axis, -1) y = np.moveaxis(y, axis, -1) z = np.broadcast(x[..., 0], y[..., 0]) x = np.broadcast_to(x, z.shape + (x.shape[-1],)) y = np.broadcast_to(y, z.shape + (y.shape[-1],)) z = np.concatenate((x, y), axis=-1) return x, y, z class _MWU: '''Distribution of MWU statistic under the null hypothesis''' # Possible improvement: if m and n are small enough, use integer arithmetic def __init__(self): '''Minimal initializer''' self._fmnks = -np.ones((1, 1, 1)) self._recursive = None def pmf(self, k, m, n): # In practice, `pmf` is never called with k > m*n/2. # If it were, we'd exploit symmetry here: # k = np.array(k, copy=True) # k2 = m*n - k # i = k2 < k # k[i] = k2[i] if (self._recursive is None and m <= 500 and n <= 500 or self._recursive): return self.pmf_recursive(k, m, n) else: return self.pmf_iterative(k, m, n) def pmf_recursive(self, k, m, n): '''Probability mass function, recursive version''' self._resize_fmnks(m, n, np.max(k)) # could loop over just the unique elements, but probably not worth # the time to find them for i in np.ravel(k): self._f(m, n, i) return self._fmnks[m, n, k] / special.binom(m + n, m) def pmf_iterative(self, k, m, n): '''Probability mass function, iterative version''' fmnks = {} for i in np.ravel(k): fmnks = _mwu_f_iterative(m, n, i, fmnks) return (np.array([fmnks[(m, n, ki)] for ki in k]) / special.binom(m + n, m)) def cdf(self, k, m, n): '''Cumulative distribution function''' # In practice, `cdf` is never called with k > m*n/2. # If it were, we'd exploit symmetry here rather than in `sf` pmfs = self.pmf(np.arange(0, np.max(k) + 1), m, n) cdfs = np.cumsum(pmfs) return cdfs[k] def sf(self, k, m, n): '''Survival function''' # Note that both CDF and SF include the PMF at k. The p-value is # calculated from the SF and should include the mass at k, so this # is desirable # Use the fact that the distribution is symmetric; i.e. # _f(m, n, m*n-k) = _f(m, n, k), and sum from the left kc = np.asarray(m*n - k) # complement of k i = k < kc if np.any(i): kc[i] = k[i] cdfs = np.asarray(self.cdf(kc, m, n)) cdfs[i] = 1. - cdfs[i] + self.pmf(kc[i], m, n) else: cdfs = np.asarray(self.cdf(kc, m, n)) return cdfs[()] def _resize_fmnks(self, m, n, k): '''If necessary, expand the array that remembers PMF values''' # could probably use `np.pad` but I'm not sure it would save code shape_old = np.array(self._fmnks.shape) shape_new = np.array((m+1, n+1, k+1)) if np.any(shape_new > shape_old): shape = np.maximum(shape_old, shape_new) fmnks = -np.ones(shape) # create the new array m0, n0, k0 = shape_old fmnks[:m0, :n0, :k0] = self._fmnks # copy remembered values self._fmnks = fmnks def _f(self, m, n, k): '''Recursive implementation of function of [3] Theorem 2.5''' # [3] Theorem 2.5 Line 1 if k < 0 or m < 0 or n < 0 or k > m*n: return 0 # if already calculated, return the value if self._fmnks[m, n, k] >= 0: return self._fmnks[m, n, k] if k == 0 and m >= 0 and n >= 0: # [3] Theorem 2.5 Line 2 fmnk = 1 else: # [3] Theorem 2.5 Line 3 / Equation 3 fmnk = self._f(m-1, n, k-n) + self._f(m, n-1, k) self._fmnks[m, n, k] = fmnk # remember result return fmnk # Maintain state for faster repeat calls to mannwhitneyu w/ method='exact' _mwu_state = _MWU() def _mwu_f_iterative(m, n, k, fmnks): '''Iterative implementation of function of [3] Theorem 2.5''' def _base_case(m, n, k): '''Base cases from recursive version''' # if already calculated, return the value if fmnks.get((m, n, k), -1) >= 0: return fmnks[(m, n, k)] # [3] Theorem 2.5 Line 1 elif k < 0 or m < 0 or n < 0 or k > m*n: return 0 # [3] Theorem 2.5 Line 2 elif k == 0 and m >= 0 and n >= 0: return 1 return None stack = [(m, n, k)] fmnk = None while stack: # Popping only if necessary would save a tiny bit of time, but NWI. m, n, k = stack.pop() # If we're at a base case, continue (stack unwinds) fmnk = _base_case(m, n, k) if fmnk is not None: fmnks[(m, n, k)] = fmnk continue # If both terms are base cases, continue (stack unwinds) f1 = _base_case(m-1, n, k-n) f2 = _base_case(m, n-1, k) if f1 is not None and f2 is not None: # [3] Theorem 2.5 Line 3 / Equation 3 fmnk = f1 + f2 fmnks[(m, n, k)] = fmnk continue # recurse deeper stack.append((m, n, k)) if f1 is None: stack.append((m-1, n, k-n)) if f2 is None: stack.append((m, n-1, k)) return fmnks def _get_mwu_z(U, n1, n2, t, axis=0, continuity=True): '''Standardized MWU statistic''' # Follows mannwhitneyu [2] mu = n1 * n2 / 2 n = n1 + n2 # Tie correction according to [2], "Normal approximation and tie correction" # "A more computationally-efficient form..." tie_term = (t**3 - t).sum(axis=-1) s = np.sqrt(n1*n2/12 * ((n + 1) - tie_term/(n*(n-1)))) numerator = U - mu # Continuity correction. # Because SF is always used to calculate the p-value, we can always # _subtract_ 0.5 for the continuity correction. This always increases the # p-value to account for the rest of the probability mass _at_ q = U. if continuity: numerator -= 0.5 # no problem evaluating the norm SF at an infinity with np.errstate(divide='ignore', invalid='ignore'): z = numerator / s return z def _mwu_input_validation(x, y, use_continuity, alternative, axis, method): ''' Input validation and standardization for mannwhitneyu ''' # Would use np.asarray_chkfinite, but infs are OK x, y = np.atleast_1d(x), np.atleast_1d(y) if np.isnan(x).any() or np.isnan(y).any(): raise ValueError('`x` and `y` must not contain NaNs.') if np.size(x) == 0 or np.size(y) == 0: raise ValueError('`x` and `y` must be of nonzero size.') bools = {True, False} if use_continuity not in bools: raise ValueError(f'`use_continuity` must be one of {bools}.') alternatives = {"two-sided", "less", "greater"} alternative = alternative.lower() if alternative not in alternatives: raise ValueError(f'`alternative` must be one of {alternatives}.') axis_int = int(axis) if axis != axis_int: raise ValueError('`axis` must be an integer.') if not isinstance(method, stats.PermutationMethod): methods = {"asymptotic", "exact", "auto"} method = method.lower() if method not in methods: raise ValueError(f'`method` must be one of {methods}.') return x, y, use_continuity, alternative, axis_int, method def _mwu_choose_method(n1, n2, ties): """Choose method 'asymptotic' or 'exact' depending on input size, ties""" # if both inputs are large, asymptotic is OK if n1 > 8 and n2 > 8: return "asymptotic" # if there are any ties, asymptotic is preferred if ties: return "asymptotic" return "exact" MannwhitneyuResult = namedtuple('MannwhitneyuResult', ('statistic', 'pvalue')) @_axis_nan_policy_factory(MannwhitneyuResult, n_samples=2) def mannwhitneyu(x, y, use_continuity=True, alternative="two-sided", axis=0, method="auto"): r'''Perform the Mann-Whitney U rank test on two independent samples. The Mann-Whitney U test is a nonparametric test of the null hypothesis that the distribution underlying sample `x` is the same as the distribution underlying sample `y`. It is often used as a test of difference in location between distributions. Parameters ---------- x, y : array-like N-d arrays of samples. The arrays must be broadcastable except along the dimension given by `axis`. use_continuity : bool, optional Whether a continuity correction (1/2) should be applied. Default is True when `method` is ``'asymptotic'``; has no effect otherwise. alternative : {'two-sided', 'less', 'greater'}, optional Defines the alternative hypothesis. Default is 'two-sided'. Let *F(u)* and *G(u)* be the cumulative distribution functions of the distributions underlying `x` and `y`, respectively. Then the following alternative hypotheses are available: * 'two-sided': the distributions are not equal, i.e. *F(u) ≠ G(u)* for at least one *u*. * 'less': the distribution underlying `x` is stochastically less than the distribution underlying `y`, i.e. *F(u) > G(u)* for all *u*. * 'greater': the distribution underlying `x` is stochastically greater than the distribution underlying `y`, i.e. *F(u) < G(u)* for all *u*. Note that the mathematical expressions in the alternative hypotheses above describe the CDFs of the underlying distributions. The directions of the inequalities appear inconsistent with the natural language description at first glance, but they are not. For example, suppose *X* and *Y* are random variables that follow distributions with CDFs *F* and *G*, respectively. If *F(u) > G(u)* for all *u*, samples drawn from *X* tend to be less than those drawn from *Y*. Under a more restrictive set of assumptions, the alternative hypotheses can be expressed in terms of the locations of the distributions; see [5] section 5.1. axis : int, optional Axis along which to perform the test. Default is 0. method : {'auto', 'asymptotic', 'exact'} or `PermutationMethod` instance, optional Selects the method used to calculate the *p*-value. Default is 'auto'. The following options are available. * ``'asymptotic'``: compares the standardized test statistic against the normal distribution, correcting for ties. * ``'exact'``: computes the exact *p*-value by comparing the observed :math:`U` statistic against the exact distribution of the :math:`U` statistic under the null hypothesis. No correction is made for ties. * ``'auto'``: chooses ``'exact'`` when the size of one of the samples is less than or equal to 8 and there are no ties; chooses ``'asymptotic'`` otherwise. * `PermutationMethod` instance. In this case, the p-value is computed using `permutation_test` with the provided configuration options and other appropriate settings. Returns ------- res : MannwhitneyuResult An object containing attributes: statistic : float The Mann-Whitney U statistic corresponding with sample `x`. See Notes for the test statistic corresponding with sample `y`. pvalue : float The associated *p*-value for the chosen `alternative`. Notes ----- If ``U1`` is the statistic corresponding with sample `x`, then the statistic corresponding with sample `y` is ``U2 = x.shape[axis] * y.shape[axis] - U1``. `mannwhitneyu` is for independent samples. For related / paired samples, consider `scipy.stats.wilcoxon`. `method` ``'exact'`` is recommended when there are no ties and when either sample size is less than 8 [1]_. The implementation follows the recurrence relation originally proposed in [1]_ as it is described in [3]_. Note that the exact method is *not* corrected for ties, but `mannwhitneyu` will not raise errors or warnings if there are ties in the data. If there are ties and either samples is small (fewer than ~10 observations), consider passing an instance of `PermutationMethod` as the `method` to perform a permutation test. The Mann-Whitney U test is a non-parametric version of the t-test for independent samples. When the means of samples from the populations are normally distributed, consider `scipy.stats.ttest_ind`. See Also -------- scipy.stats.wilcoxon, scipy.stats.ranksums, scipy.stats.ttest_ind References ---------- .. [1] H.B. Mann and D.R. Whitney, "On a test of whether one of two random variables is stochastically larger than the other", The Annals of Mathematical Statistics, Vol. 18, pp. 50-60, 1947. .. [2] Mann-Whitney U Test, Wikipedia, http://en.wikipedia.org/wiki/Mann-Whitney_U_test .. [3] A. Di Bucchianico, "Combinatorics, computer algebra, and the Wilcoxon-Mann-Whitney test", Journal of Statistical Planning and Inference, Vol. 79, pp. 349-364, 1999. .. [4] Rosie Shier, "Statistics: 2.3 The Mann-Whitney U Test", Mathematics Learning Support Centre, 2004. .. [5] Michael P. Fay and Michael A. Proschan. "Wilcoxon-Mann-Whitney or t-test? On assumptions for hypothesis tests and multiple \ interpretations of decision rules." Statistics surveys, Vol. 4, pp. 1-39, 2010. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2857732/ Examples -------- We follow the example from [4]_: nine randomly sampled young adults were diagnosed with type II diabetes at the ages below. >>> males = [19, 22, 16, 29, 24] >>> females = [20, 11, 17, 12] We use the Mann-Whitney U test to assess whether there is a statistically significant difference in the diagnosis age of males and females. The null hypothesis is that the distribution of male diagnosis ages is the same as the distribution of female diagnosis ages. We decide that a confidence level of 95% is required to reject the null hypothesis in favor of the alternative that the distributions are different. Since the number of samples is very small and there are no ties in the data, we can compare the observed test statistic against the *exact* distribution of the test statistic under the null hypothesis. >>> from scipy.stats import mannwhitneyu >>> U1, p = mannwhitneyu(males, females, method="exact") >>> print(U1) 17.0 `mannwhitneyu` always reports the statistic associated with the first sample, which, in this case, is males. This agrees with :math:`U_M = 17` reported in [4]_. The statistic associated with the second statistic can be calculated: >>> nx, ny = len(males), len(females) >>> U2 = nx*ny - U1 >>> print(U2) 3.0 This agrees with :math:`U_F = 3` reported in [4]_. The two-sided *p*-value can be calculated from either statistic, and the value produced by `mannwhitneyu` agrees with :math:`p = 0.11` reported in [4]_. >>> print(p) 0.1111111111111111 The exact distribution of the test statistic is asymptotically normal, so the example continues by comparing the exact *p*-value against the *p*-value produced using the normal approximation. >>> _, pnorm = mannwhitneyu(males, females, method="asymptotic") >>> print(pnorm) 0.11134688653314041 Here `mannwhitneyu`'s reported *p*-value appears to conflict with the value :math:`p = 0.09` given in [4]_. The reason is that [4]_ does not apply the continuity correction performed by `mannwhitneyu`; `mannwhitneyu` reduces the distance between the test statistic and the mean :math:`\mu = n_x n_y / 2` by 0.5 to correct for the fact that the discrete statistic is being compared against a continuous distribution. Here, the :math:`U` statistic used is less than the mean, so we reduce the distance by adding 0.5 in the numerator. >>> import numpy as np >>> from scipy.stats import norm >>> U = min(U1, U2) >>> N = nx + ny >>> z = (U - nx*ny/2 + 0.5) / np.sqrt(nx*ny * (N + 1)/ 12) >>> p = 2 * norm.cdf(z) # use CDF to get p-value from smaller statistic >>> print(p) 0.11134688653314041 If desired, we can disable the continuity correction to get a result that agrees with that reported in [4]_. >>> _, pnorm = mannwhitneyu(males, females, use_continuity=False, ... method="asymptotic") >>> print(pnorm) 0.0864107329737 Regardless of whether we perform an exact or asymptotic test, the probability of the test statistic being as extreme or more extreme by chance exceeds 5%, so we do not consider the results statistically significant. Suppose that, before seeing the data, we had hypothesized that females would tend to be diagnosed at a younger age than males. In that case, it would be natural to provide the female ages as the first input, and we would have performed a one-sided test using ``alternative = 'less'``: females are diagnosed at an age that is stochastically less than that of males. >>> res = mannwhitneyu(females, males, alternative="less", method="exact") >>> print(res) MannwhitneyuResult(statistic=3.0, pvalue=0.05555555555555555) Again, the probability of getting a sufficiently low value of the test statistic by chance under the null hypothesis is greater than 5%, so we do not reject the null hypothesis in favor of our alternative. If it is reasonable to assume that the means of samples from the populations are normally distributed, we could have used a t-test to perform the analysis. >>> from scipy.stats import ttest_ind >>> res = ttest_ind(females, males, alternative="less") >>> print(res) Ttest_indResult(statistic=-2.239334696520584, pvalue=0.030068441095757924) Under this assumption, the *p*-value would be low enough to reject the null hypothesis in favor of the alternative. ''' x, y, use_continuity, alternative, axis_int, method = ( _mwu_input_validation(x, y, use_continuity, alternative, axis, method)) x, y, xy = _broadcast_concatenate(x, y, axis) n1, n2 = x.shape[-1], y.shape[-1] # Follows [2] ranks, t = _rankdata(xy, 'average', return_ties=True) # method 2, step 1 R1 = ranks[..., :n1].sum(axis=-1) # method 2, step 2 U1 = R1 - n1*(n1+1)/2 # method 2, step 3 U2 = n1 * n2 - U1 # as U1 + U2 = n1 * n2 if alternative == "greater": U, f = U1, 1 # U is the statistic to use for p-value, f is a factor elif alternative == "less": U, f = U2, 1 # Due to symmetry, use SF of U2 rather than CDF of U1 else: U, f = np.maximum(U1, U2), 2 # multiply SF by two for two-sided test if method == "auto": method = _mwu_choose_method(n1, n2, np.any(t > 1)) if method == "exact": p = _mwu_state.sf(U.astype(int), min(n1, n2), max(n1, n2)) elif method == "asymptotic": z = _get_mwu_z(U, n1, n2, t, continuity=use_continuity) p = stats.norm.sf(z) else: # `PermutationMethod` instance (already validated) def statistic(x, y, axis): return mannwhitneyu(x, y, use_continuity=use_continuity, alternative=alternative, axis=axis, method="asymptotic").statistic res = stats.permutation_test((x, y), statistic, axis=axis, **method._asdict(), alternative=alternative) p = res.pvalue f = 1 p *= f # Ensure that test statistic is not greater than 1 # This could happen for exact test when U = m*n/2 p = np.clip(p, 0, 1) return MannwhitneyuResult(U1, p)