コード例 #1
0
ファイル: test_models_optim.py プロジェクト: maxibor/pydamage
def test_null_model_optim(generate_data):
    u = models.null_model()
    o, e = optim(function=u.fit,
                 parameters=u.kwds,
                 xdata=generate_data[1],
                 ydata=generate_data[2],
                 bounds=u.bounds,
                 loss='linear')
    assert o == {'p0': 0.1000000000000005}
コード例 #2
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def test_unif_optim(generate_data):
    u = models.unif_mod()
    o, e = optim(function=u.pmf,
                 parameters=u.kwds,
                 xdata=generate_data[1],
                 ydata=generate_data[2],
                 bounds=u.bounds,
                 loss='linear')
    assert o == {'unif_pmin': 0.1000000000000005}
コード例 #3
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def test_geom_optim(generate_data):
    g = models.geom_mod()
    o, e = optim(function=g.pmf,
                 parameters=g.kwds,
                 xdata=generate_data[1],
                 ydata=generate_data[2],
                 bounds=g.bounds,
                 loss='linear')

    target = {
        'geom_p': 0.6039535547658853,
        'geom_pmin': 0.03637474931290336,
        'geom_pmax': 0.4211432052501663
    }
    for k in o:
        assert round(o[k], 3) == round(target[k], 3)
コード例 #4
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        0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1
    ]).all()


def test_unif_log_pmf(generate_data):
    u = models.unif_mod()
    assert u.log_pmf(x=generate_data[0], unif_pmin=0.1).all() == np.array([
        -2.30258509, -2.30258509, -2.30258509, -2.30258509, -2.30258509,
        -2.30258509, -2.30258509, -2.30258509, -2.30258509, -2.30258509,
        -2.30258509, -2.30258509, -2.30258509, -2.30258509, -2.30258509,
        -2.30258509, -2.30258509, -2.30258509, -2.30258509, -2.30258509,
        -2.30258509, -2.30258509, -2.30258509, -2.30258509
    ]).all()


def test_unif_optim(generate_data):
    u = models.unif_mod()
    o, e = optim(function=u.pmf,
                 parameters=u.kwds,
                 xdata=generate_data[1],
                 ydata=generate_data[2],
                 bounds=u.bounds,
                 loss='linear')
    assert o == {'unif_pmin': 0.1000000000000005}


if __name__ == "__main__":
    data, xdata, ydata = generate_data()
    g = models.geom_mod()
    o = optim(function=g.pmf, parameters=g.kwds, xdata=xdata, ydata=ydata)
コード例 #5
0
def fit_models(ref, model_A, model_B, ct_data, cc_data, ga_data, all_bases,
               wlen, verbose):
    """Performs model fitting and runs Vuong's closeness test

    Args:
        ref (str): name of referene in alignment file
        model_A (pydamage.models): Pydamage H1 Damage model
        model_B (pydamage.models): Pydamage H0 Null model
        ct_data (list of int): List of positions where CtoT transitions were observed
        ga_data (list of int): List of positions where GtoA transitions were observed
        cc_data (list of int): List of positions where C in ref and query
        all_bases (list of int): List of positions where a base is aligned
        wlen (int): window length
        verbose (bool): verbose mode
    """
    all_bases_pos, all_bases_counts = np.unique(np.sort(all_bases),
                                                return_counts=True)
    c2t_pos, c2t_counts = np.unique(np.sort(ct_data), return_counts=True)
    g2a_pos, g2a_counts = np.unique(np.sort(ga_data), return_counts=True)
    c2t = dict(zip(c2t_pos, c2t_counts))
    g2a = dict(zip(g2a_pos, g2a_counts))

    # Getting Positions and counts of C2C and C2T
    c2t_dict, c2c_dict = create_ct_cc_dict(ct_data=ct_data,
                                           cc_data=cc_data,
                                           wlen=wlen)

    # Adding zeros at positions where no damage is observed
    for i in all_bases_pos:
        if all_bases_counts[i] > 0:
            if i not in c2t:
                c2t[i] = 0
            if i not in g2a:
                g2a[i] = 0
    c2t = sort_dict_by_keys(c2t)
    g2a = sort_dict_by_keys(g2a)

    xdata = np.array(list(c2t.keys()))
    counts = np.array(list(c2t.values()))

    ydata = list(counts / counts.sum())
    qlen = len(ydata)
    ydata_counts = {i: c for i, c in enumerate(ydata)}
    ctot_out = {f"CtoT-{k}": v for k, v in enumerate(ydata)}

    g2a_counts = np.array(list(g2a.values()))
    y_ga = list(g2a_counts / g2a_counts.sum())
    gtoa_out = {f"GtoA-{k}": v for k, v in enumerate(y_ga)}

    for i in range(qlen):
        if i not in ydata_counts:
            ydata_counts[i] = np.nan
        if f"CtoT-{i}" not in ctot_out:
            ctot_out[f"CtoT-{i}"] = np.nan
        if f"GtoA-{i}" not in gtoa_out:
            gtoa_out[f"GtoA-{i}"] = np.nan

    #################
    # MODEL FITTING #
    #################

    # Only fitting model to interval [0,wlen]
    xdata = xdata[:wlen]
    ydata = ydata[:wlen]

    res = {}
    optim_A, stdev_A = optim(
        function=model_A.pmf,  # damage model
        parameters=model_A.kwds,
        xdata=xdata,
        ydata=ydata,
        bounds=model_A.bounds)
    if optim_A['geom_pmax'] < optim_A[
            'geom_pmin']:  # making sure that fitting makes sense
        optim_A['geom_pmax'] = optim_A['geom_pmin']

    optim_B, stdev_B = optim(
        function=model_B.pmf,  # null model
        parameters=model_B.kwds,
        xdata=xdata,
        ydata=ydata,
        bounds=model_B.bounds)

    ##########################
    # LIKELIHOOD CALCULATION #
    ##########################

    # position of sites where C in reference
    c_sites = np.array(list(c2t_dict.keys()))
    # counts of C2T at each site
    c2t_count_per_site = np.array(list(c2t_dict.values()))
    # counts of C2C at each site
    c2c_count_per_site = np.array(list(c2c_dict.values()))

    # Likelihood for model A - Damage Model
    # For C2T events
    LA_CT_base = model_A.log_pmf(x=c_sites, wlen=wlen, **optim_A)
    LA_CT = LA_CT_base * c2t_count_per_site

    # For C2C events
    LA_CC_base = np.log(1 - model_A.pmf(x=c_sites, wlen=wlen, **optim_A))
    LA_CC = LA_CC_base * c2c_count_per_site

    LA = LA_CT + LA_CC

    # Likelihood for model B - Null Model
    # For C2T events
    LB_CT_base = model_B.log_pmf(x=c_sites, **optim_B)
    LB_CT = LB_CT_base * c2t_count_per_site

    # For C2C events
    LB_CC_base = np.log(1 - model_B.pmf(x=c_sites, **optim_B))
    LB_CC = LB_CC_base * c2c_count_per_site

    LB = LB_CT + LB_CC

    # Difference of number of paramters between model A and model B
    pdiff = len(model_A.kwds) - len(model_B.kwds)

    ################
    # VUONG'S TEST #
    ################

    zscore, pval = vuong_closeness(LA=LA, LB=LB, N=wlen, pdiff=pdiff)

    res.update(ydata_counts)
    res.update(ctot_out)
    res.update(gtoa_out)
    res.update(optim_A)
    res.update(stdev_A)
    res.update(optim_B)
    res.update(stdev_B)
    res.update({'pvalue': pval})
    res.update({'base_cov': all_bases_counts})
    res.update({
        'model_params':
        list(optim_A.values()) + list(optim_B.values()) +
        list(stdev_A.values()) + list(stdev_B.values())
    })
    res['qlen'] = qlen
    res['residuals'] = ydata - model_A.pmf(x=xdata, **optim_A)
    res['RMSE'] = RMSE(res['residuals'])
    return (res)
コード例 #6
0
def fit_models(
    ref, model_A, model_B, ct_data, cc_data, ga_data, all_bases, wlen, verbose
):
    """Performs model fitting and runs Likelihood ratio test

    Args:
        ref (str): name of referene in alignment file
        model_A (pydamage.models): Pydamage H1 Damage model
        model_B (pydamage.models): Pydamage H0 Null model
        ct_data (list of int): List of positions where CtoT transitions were observed
        ga_data (list of int): List of positions where GtoA transitions were observed
        cc_data (list of int): List of positions where C in ref and query
        all_bases (list of int): List of positions where a base is aligned
        wlen (int): window length
        verbose (bool): verbose mode
    """
    all_bases_pos, all_bases_counts = np.unique(np.sort(all_bases), return_counts=True)
    c2t_pos, c2t_counts = np.unique(np.sort(ct_data), return_counts=True)
    g2a_pos, g2a_counts = np.unique(np.sort(ga_data), return_counts=True)
    c2t = dict(zip(c2t_pos, c2t_counts))
    g2a = dict(zip(g2a_pos, g2a_counts))

    # Getting Positions and counts of C2C and C2T
    c2t_dict, c2c_dict = create_ct_cc_dict(ct_data=ct_data, cc_data=cc_data, wlen=wlen)

    # Adding zeros at positions where no damage is observed
    for i in all_bases_pos:
        if i < len(all_bases_counts):
            if all_bases_counts[i] > 0:
                if i not in c2t:
                    c2t[i] = 0
                if i not in g2a:
                    g2a[i] = 0
    c2t = sort_dict_by_keys(c2t)
    g2a = sort_dict_by_keys(g2a)

    xdata = np.array(list(c2t.keys()))
    counts = np.array(list(c2t.values()))

    ydata = list(counts / counts.sum())
    qlen = len(ydata)
    ydata_counts = {i: c for i, c in enumerate(ydata)}
    ctot_out = {f"CtoT-{k}": v for k, v in enumerate(ydata)}

    g2a_counts = np.array(list(g2a.values()))
    y_ga = list(g2a_counts / g2a_counts.sum())
    gtoa_out = {f"GtoA-{k}": v for k, v in enumerate(y_ga)}

    for i in range(qlen):
        if i not in ydata_counts:
            ydata_counts[i] = np.nan
        if f"CtoT-{i}" not in ctot_out:
            ctot_out[f"CtoT-{i}"] = np.nan
        if f"GtoA-{i}" not in gtoa_out:
            gtoa_out[f"GtoA-{i}"] = np.nan

    #################
    # MODEL FITTING #
    #################

    # Only fitting model to interval [0,wlen]
    xdata = xdata[:wlen]
    ydata = ydata[:wlen]

    res = {}
    optim_A, stdev_A = optim(
        function=model_A.fit,  # damage model
        parameters=model_A.kwds,
        xdata=xdata,
        ydata=ydata,
        bounds=model_A.bounds,
    )
    if optim_A["pmax"] < optim_A["pmin"]:  # making sure that fitting makes sense
        optim_A["pmax"] = optim_A["pmin"]

    optim_B, stdev_B = optim(
        function=model_B.fit,  # null model
        parameters=model_B.kwds,
        xdata=xdata,
        ydata=ydata,
        bounds=model_B.bounds,
    )

    ##########################
    # LIKELIHOOD CALCULATION #
    ##########################

    # position of sites where C in reference
    c_sites = np.array(list(c2t_dict.keys()))
    # counts of C2C at each site
    c2c_count_per_site = np.array(list(c2c_dict.values()))
    # counts of C2T at each site
    binom_k = np.array(list(c2t_dict.values()))
    # all C per site
    binom_n = c2c_count_per_site + binom_k

    # Likelihood for model A - Damage Model
    binom_p_damage = model_A.fit(c_sites, **optim_A)
    LA = binom.logpmf(k=binom_k, n=binom_n, p=binom_p_damage)

    # Likelihood for model B - Null Model
    binom_p_null = model_B.fit(c_sites, **optim_B)
    LB = binom.logpmf(k=binom_k, n=binom_n, p=binom_p_null)

    # Difference of number of paramters between model A and model B
    pdiff = len(model_A.kwds) - len(model_B.kwds)

    ################
    # LR TEST #
    ################

    LR_lambda, pval = LR(L0=LB, L1=LA, df=pdiff)

    res.update(ydata_counts)
    res.update(ctot_out)
    res.update(gtoa_out)
    res.update(optim_A)
    res.update(stdev_A)
    res.update(optim_B)
    res.update(stdev_B)
    res.update({"pvalue": pval})
    res.update({"base_cov": all_bases_counts})
    res.update(
        {
            "model_params": list(optim_A.values())
            + list(optim_B.values())
            + list(stdev_A.values())
            + list(stdev_B.values())
        }
    )
    res["qlen"] = qlen
    res["residuals"] = ydata - model_A.fit(x=xdata, **optim_A)
    res["RMSE"] = RMSE(res["residuals"])
    res["wlen"] = wlen
    return res
コード例 #7
0
def fit_models(
    ref,
    model_A,
    model_B,
    damage,
    mut_count,
    conserved_count,
    verbose,
):
    """Performs model fitting and runs Likelihood ratio test

    Args:
        ref (str): name of referene in alignment file
        model_A (pydamage.models): Pydamage H1 Damage model
        model_B (pydamage.models): Pydamage H0 Null model
        damage (np.array of float): Amount of damage at each position where CtoT or GtoA (if reversed) transitions were observed
        mut_count(np.array of int): Number of CtoT and GtoA per position
        conserved_count(np.array of int): Number of conserved C and G per position
        verbose (bool): verbose mode
    """
    #################
    # MODEL FITTING #
    #################

    # Only fitting model to interval [0,wlen]
    xdata = np.arange(damage.size)

    res = {}
    optim_A, stdev_A = optim(
        function=model_A.fit,  # damage model
        parameters=model_A.kwds,
        xdata=xdata,
        ydata=damage,
        bounds=model_A.bounds,
    )
    if optim_A["pmax"] < optim_A[
            "pmin"]:  # making sure that fitting makes sense
        optim_A["pmax"] = optim_A["pmin"]

    optim_B, stdev_B = optim(
        function=model_B.fit,  # null model
        parameters=model_B.kwds,
        xdata=xdata,
        ydata=damage,
        bounds=model_B.bounds,
    )

    ##########################
    # LIKELIHOOD CALCULATION #
    ##########################

    # position of sites where C in reference
    c_sites = xdata
    # counts of conserved positions at each site
    c2c_count_per_site = conserved_count
    # counts of CtoT and GtoA mutations at each site
    binom_k = mut_count
    # all C per site
    binom_n = c2c_count_per_site + binom_k

    # Likelihood for model A - Damage Model
    binom_p_damage = model_A.fit(c_sites, **optim_A)
    LA = binom.logpmf(k=binom_k, n=binom_n, p=binom_p_damage)

    # Likelihood for model B - Null Model
    binom_p_null = model_B.fit(c_sites, **optim_B)
    LB = binom.logpmf(k=binom_k, n=binom_n, p=binom_p_null)

    # Difference of number of paramters between model A and model B
    pdiff = len(model_A.kwds) - len(model_B.kwds)

    ################
    # LR TEST #
    ################

    LR_lambda, pval = LR(L0=LB, L1=LA, df=pdiff)

    res.update(optim_A)
    res.update(stdev_A)
    res.update(optim_B)
    res.update(stdev_B)
    res.update({"pvalue": pval})
    res.update({
        "model_params":
        list(optim_A.values()) + list(optim_B.values()) +
        list(stdev_A.values()) + list(stdev_B.values())
    })
    res["residuals"] = damage - model_A.fit(x=xdata, **optim_A)
    res["RMSE"] = RMSE(res["residuals"])
    return res