示例#1
0
文件: main.py 项目: fredstro/lmfdb
def download_search(info):
    dltype = info["Submit"]
    delim = "bracket"
    com = r"\\"  # single line comment start
    com1 = ""  # multiline comment start
    com2 = ""  # multiline comment end
    filename = "elliptic_curves.gp"
    mydate = time.strftime("%d %B %Y")
    if dltype == "sage":
        com = "#"
        filename = "elliptic_curves.sage"
    if dltype == "magma":
        com = ""
        com1 = "/*"
        com2 = "*/"
        delim = "magma"
        filename = "elliptic_curves.m"
    s = com1 + "\n"
    s += com + " Elliptic curves downloaded from the LMFDB downloaded on %s.\n" % (mydate)
    s += com + " Below is a list called data. Each entry has the form:\n"
    s += com + "   [[field_poly],[Weierstrass Coefficients, constant first in increasing degree]]\n"
    s += "\n" + com2
    s += "\n"

    if dltype == "magma":
        s += "P<x> := PolynomialRing(Rationals()); \n"
        s += "data := ["
    elif dltype == "sage":
        s += "x = polygen(QQ) \n"
        s += "data = [ "
    else:
        s += "data = [ "
    s += "\\\n"
    nf_dict = {}
    res = db_ecnf().find(ast.literal_eval(info["query"]))
    for f in res:
        nf = str(f["field_label"])
        # look up number field and see if we already have the min poly
        if nf in nf_dict:
            poly = nf_dict[nf]
        else:
            poly = str(WebNumberField(f["field_label"]).poly())
            nf_dict[nf] = poly
        entry = str(f["ainvs"])
        entry = entry.replace("u", "")
        entry = entry.replace("'", "")
        s += "[[" + poly + "], " + entry + "],\\\n"
    s = s[:-3]
    s += "]\n"
    if delim == "brace":
        s = s.replace("[", "{")
        s = s.replace("]", "}")
    if delim == "magma":
        s = s.replace("[", "[*")
        s = s.replace("]", "*]")
        s += ";"
    strIO = StringIO.StringIO()
    strIO.write(s)
    strIO.seek(0)
    return send_file(strIO, attachment_filename=filename, as_attachment=True)
示例#2
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 def __init__(self):
     logger.debug("Constructing an instance of ECstats")
     self.ecdb = db_ecnf()
     self._counts = {}
     self._stats = {}
     self._dstats = {}
     self._sigstats = {}
示例#3
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    def make_torsion_growth(self):
        try:
            tor_gro = self.tor_gro
            self.torsion_growth_data_exists = True
        except AttributeError:
            self.torsion_growth_data_exists = False
            return

        self.tg = tg = {}
        tg['data'] = tgextra = []
        # find all base-changes of this curve in the database, if any
        from lmfdb.ecnf.WebEllipticCurve import db_ecnf
        bcs = [
            res['label']
            for res in db_ecnf().find({'base_change': self.lmfdb_label},
                                      projection={
                                          'label': True,
                                          '_id': False
                                      })
        ]
        bcfs = [lab.split("-")[0] for lab in bcs]
        for F, T in tor_gro.items():
            tg1 = {}
            tg1['bc'] = "Not in database"
            if ":" in F:
                F = F.replace(":", ".")
                field_data = nf_display_knowl(F, getDBConnection(),
                                              field_pretty(F))
                deg = int(F.split(".")[0])
                bcc = [x for x, y in zip(bcs, bcfs) if y == F]
                if bcc:
                    from lmfdb.ecnf.main import split_full_label
                    F, NN, I, C = split_full_label(bcc[0])
                    tg1['bc'] = bcc[0]
                    tg1['bc_url'] = url_for('ecnf.show_ecnf',
                                            nf=F,
                                            conductor_label=NN,
                                            class_label=I,
                                            number=C)
            else:
                field_data = web_latex_split_on_pm(
                    coeff_to_poly(string2list(F)))
                deg = F.count(",")
            tg1['d'] = deg
            tg1['f'] = field_data
            tg1['t'] = '\(' + ' \\times '.join(
                ['\Z/{}\Z'.format(n) for n in T.split(",")]) + '\)'
            tg1['m'] = 0
            tgextra.append(tg1)

        tgextra.sort(key=lambda x: x['d'])
        tg['n'] = len(tgextra)
        lastd = 1
        for tg1 in tgextra:
            d = tg1['d']
            if d != lastd:
                tg1['m'] = len([x for x in tgextra if x['d'] == d])
                lastd = d
        tg['maxd'] = max(db_ecstats().find_one({'_id':
                                                'torsion_growth'})['degrees'])
示例#4
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 def __init__(self):
     logger.debug("Constructing an instance of ECstats")
     self.ecdb = db_ecnf()
     self._counts = {}
     self._stats = {}
     self._dstats = {}
     self._sigstats = {}
示例#5
0
文件: main.py 项目: riiduan/lmfdb
def show_ecnf1(nf):
    if nf == "1.1.1.1":
        return redirect(url_for("ec.rational_elliptic_curves", **request.args))
    if request.args:
        return elliptic_curve_search(data=request.args)
    start = 0
    count = 50
    try:
        nf_label = nf_string_to_label(nf)
    except ValueError:
        return search_input_error()
    query = {'field_label': nf_label}
    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if (start >= nres):
        start -= (1 + (start - nres) / count) * count
    if (start < 0):
        start = 0

    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC),
                       ('conductor_label', ASC), ('iso_nlabel', ASC),
                       ('number', ASC)]).skip(start).limit(count)

    bread = [('Elliptic Curves', url_for(".index")),
             (nf_label, url_for('.show_ecnf1', nf=nf_label))]

    res = list(res)
    for e in res:
        e['field_knowl'] = nf_display_knowl(e['field_label'],
                                            getDBConnection(),
                                            field_pretty(e['field_label']))
    info = {}
    info['field'] = nf_label
    info['query'] = query
    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    #don't risk recomputing all the ecnf stats just to show curves for a single number field
    #if nf_label:
    #info['stats'] = ecnf_field_summary(nf_label)
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (
                start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curves over %s' % field_pretty(nf_label)
    return render_template("ecnf-search-results.html",
                           info=info,
                           credit=ecnf_credit,
                           bread=bread,
                           title=t,
                           learnmore=learnmore_list())
示例#6
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def random_curve():
    E = random_object_from_collection(db_ecnf())
    return redirect(
        url_for(".show_ecnf",
                nf=E['field_label'],
                conductor_label=E['conductor_label'],
                class_label=E['iso_label'],
                number=E['number']), 307)
示例#7
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def index():
    #    if 'jump' in request.args:
    #        return show_ecnf1(request.args['label'])
    if len(request.args) > 0:
        return elliptic_curve_search(data=request.args)
    bread = get_bread()
    data = {}
    nfs = db_ecnf().distinct("field_label")
    nfs = ["2.0.4.1", "2.2.5.1", "3.1.23.1"]
    data["fields"] = [(nf, field_pretty(nf)) for nf in nfs if int(nf.split(".")[2]) < 200]
    return render_template("ecnf-index.html", title="Elliptic Curves over Number Fields", data=data, bread=bread)
示例#8
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    def by_label(label):
        """
        Searches for a specific elliptic curve isogeny class in the
        curves collection by its label, which can be either a full
        curve label (including the field_label component) or a full
        class label.  In either case the data will be obtained from
        the curve in the database with number 1 in the class.
        """
        #print "label = %s" % label
        try:
            if label[-1].isdigit():
                data = db_ecnf().find_one({"label": label})
            else:
                data = db_ecnf().find_one({"label": label + "1"})
        except AttributeError:
            return "Invalid label"  # caller must catch this and raise an error

        if data:
            return ECNF_isoclass(data)
        return "Class not found"  # caller must catch this and raise an error
示例#9
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    def by_label(label):
        """
        Searches for a specific elliptic curve isogeny class in the
        curves collection by its label, which can be either a full
        curve label (including the field_label component) or a full
        class label.  In either case the data will be obtained from
        the curve in the database with number 1 in the class.
        """
        #print "label = %s" % label
        try:
            if label[-1].isdigit():
                data = db_ecnf().find_one({"label": label})
            else:
                data = db_ecnf().find_one({"label": label + "1"})
        except AttributeError:
            return "Invalid label"  # caller must catch this and raise an error

        if data:
            return ECNF_isoclass(data)
        return "Class not found"  # caller must catch this and raise an error
示例#10
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文件: main.py 项目: sfrechet/lmfdb
def show_ecnf1(nf):
    if nf == "1.1.1.1":
        return redirect(url_for("ec.rational_elliptic_curves", **request.args))
    if request.args:
        return elliptic_curve_search(data=request.args)
    start = 0
    count = 50
    nf_label = parse_field_string(nf)
    query = {"field_label": nf_label}
    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if start >= nres:
        start -= (1 + (start - nres) / count) * count
    if start < 0:
        start = 0
    res = (
        cursor.sort(
            [
                ("field_label", ASC),
                ("conductor_norm", ASC),
                ("conductor_label", ASC),
                ("iso_label", ASC),
                ("number", ASC),
            ]
        )
        .skip(start)
        .limit(count)
    )

    bread = [("Elliptic Curves", url_for(".index")), (nf_label, url_for(".show_ecnf1", nf=nf_label))]

    res = list(res)
    for e in res:
        e["field_knowl"] = nf_display_knowl(e["field_label"], getDBConnection(), e["field_label"])
    info = {}
    info["field"] = nf_label
    info["query"] = query
    info["curves"] = res  # [ECNF(e) for e in res]
    info["number"] = nres
    info["start"] = start
    info["count"] = count
    info["more"] = int(start + count < nres)
    info["field_pretty"] = field_pretty
    info["web_ainvs"] = web_ainvs
    if nres == 1:
        info["report"] = "unique match"
    else:
        if nres > count or start != 0:
            info["report"] = "displaying matches %s-%s of %s" % (start + 1, min(nres, start + count), nres)
        else:
            info["report"] = "displaying all %s matches" % nres
    t = "Elliptic Curves over %s" % field_pretty(nf_label)
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#11
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文件: main.py 项目: fredstro/lmfdb
def random_curve():
    E = random_object_from_collection(db_ecnf())
    return redirect(
        url_for(
            ".show_ecnf",
            nf=E["field_label"],
            conductor_label=E["conductor_label"],
            class_label=E["iso_label"],
            number=E["number"],
        ),
        301,
    )
示例#12
0
文件: main.py 项目: akoutsianas/lmfdb
def show_ecnf1(nf):
    if nf == "1.1.1.1":
        return redirect(url_for("ec.rational_elliptic_curves", **request.args))
    if request.args:
        return elliptic_curve_search(data=request.args)
    start = 0
    count = 50
    try:
        nf_label = nf_string_to_label(nf)
    except ValueError:
        return search_input_error()
    query = {'field_label': nf_label}
    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if(start >= nres):
        start -= (1 + (start - nres) / count) * count
    if(start < 0):
        start = 0

    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC), ('conductor_label', ASC), ('iso_nlabel', ASC), ('number', ASC)]).skip(start).limit(count)

    bread = [('Elliptic Curves', url_for(".index")),
             (nf_label, url_for('.show_ecnf1', nf=nf_label))]

    res = list(res)
    for e in res:
        e['field_knowl'] = nf_display_knowl(e['field_label'], getDBConnection(), field_pretty(e['field_label']))
    info = {}
    info['field'] = nf_label
    info['query'] = query
    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    #don't risk recomputing all the ecnf stats just to show curves for a single number field
    #if nf_label:
        #info['stats'] = ecnf_field_summary(nf_label)
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curves over %s' % field_pretty(nf_label)
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t, learnmore=learnmore_list())
示例#13
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def download_ECNF_all(nf,conductor_label,class_label,number):
    conductor_label = unquote(conductor_label)
    conductor_label = convert_IQF_label(nf,conductor_label)
    try:
        nf_label = nf_string_to_label(nf)
    except ValueError:
        return search_input_error()
    label = "".join(["-".join([nf_label, conductor_label, class_label]), number])
    data = db_ecnf().find_one({'label':label}, {'_id':False})
    if data is None:
        return search_input_error()

    import json
    response = make_response(json.dumps(data))
    response.headers['Content-type'] = 'text/plain'
    return response
示例#14
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def download_ECNF_all(nf,conductor_label,class_label,number):
    conductor_label = unquote(conductor_label)
    conductor_label = convert_IQF_label(nf,conductor_label)
    try:
        nf_label = nf_string_to_label(nf)
    except ValueError:
        return search_input_error()
    label = "".join(["-".join([nf_label, conductor_label, class_label]), number])
    data = db_ecnf().find_one({'label':label}, {'_id':False})
    if data is None:
        return search_input_error()

    import json
    response = make_response(json.dumps(data))
    response.headers['Content-type'] = 'text/plain'
    return response
示例#15
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    def make_torsion_growth(self):
        try:
            tor_gro = self.tor_gro
            self.torsion_growth_data_exists = True
        except AttributeError:
            self.torsion_growth_data_exists = False
            return

        self.tg = tg = {}
        tg['data'] = tgextra = []
        # find all base-changes of this curve in the database, if any
        from lmfdb.ecnf.WebEllipticCurve import db_ecnf
        bcs = [res['label'] for res in  db_ecnf().find({'base_change': self.lmfdb_label}, projection={'label': True, '_id': False})]
        bcfs = [lab.split("-")[0] for lab in bcs]
        for F, T in tor_gro.items():
            tg1 = {}
            tg1['bc'] = "Not in database"
            if ":" in F:
                F = F.replace(":",".")
                field_data = nf_display_knowl(F, getDBConnection(), field_pretty(F))
                deg = int(F.split(".")[0])
                bcc = [x for x,y in zip(bcs, bcfs) if y==F]
                if bcc:
                    from lmfdb.ecnf.main import split_full_label
                    F, NN, I, C = split_full_label(bcc[0])
                    tg1['bc'] = bcc[0]
                    tg1['bc_url'] = url_for('ecnf.show_ecnf', nf=F, conductor_label=NN, class_label=I, number=C)
            else:
                field_data = web_latex_split_on_pm(coeff_to_poly(string2list(F)))
                deg = F.count(",")
            tg1['d'] = deg
            tg1['f'] = field_data
            tg1['t'] = '\(' + ' \\times '.join(['\Z/{}\Z'.format(n) for n in T.split(",")]) + '\)'
            tg1['m'] = 0
            tgextra.append(tg1)

        tgextra.sort(key = lambda x: x['d'])
        tg['n'] = len(tgextra)
        lastd = 1
        for tg1 in tgextra:
            d = tg1['d']
            if d!=lastd:
                tg1['m'] = len([x for x in tgextra if x['d']==d])
                lastd = d
        tg['maxd'] = max(db_ecstats().find_one({'_id': 'torsion_growth'})['degrees'])
示例#16
0
文件: main.py 项目: elguindy/lmfdb
def show_ecnf1(nf):
    if request.args:
        return elliptic_curve_search(data=request.args)
    start = 0
    count = 20
    query = {'field_label' : nf}
    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if(start >= nres):
        start -= (1 + (start - nres) / count) * count
    if(start < 0):
        start = 0
    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC), ('conductor_label', ASC), ('iso_label', ASC), ('number', ASC)]).skip(start).limit(count)

    bread = [('Elliptic Curves', url_for(".index")),
             (nf, url_for('.show_ecnf1', nf=nf))]

    res = list(res)
    for e in res:
        e['field_knowl'] = nf_display_knowl(e['field_label'], getDBConnection(), e['field_label'])
    info = {}
    info['field'] = nf
    info['query'] = query
    info['curves'] = res # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curves over %s' % field_pretty(nf)
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#17
0
    def make_class(self):

        # Create a list of the curves in the class from the database
        self.db_curves = [
            c for c in db_ecnf().find({
                'field_label': self.field_label,
                'conductor_norm': self.conductor_norm,
                'conductor_label': self.conductor_label,
                'iso_nlabel': self.iso_nlabel
            }).sort('number')
        ]

        # Rank or bounds
        try:
            self.rk = web_latex(self.db_curves[0]['rank'])
        except KeyError:
            self.rk = "?"
        try:
            self.rk_bnds = "%s...%s" % tuple(self.db_curves[0]['rank_bounds'])
        except KeyError:
            self.rank_bounds = [0, Infinity]
            self.rk_bnds = "not recorded"

        # Extract the isogeny degree matrix from the database
        if not hasattr(self, 'isogeny_matrix'):
            # this would happen if the class is initiated with a curve
            # which is not #1 in its class:
            self.isogeny_matrix = self.db_curves[0].isogeny_matrix
        self.isogeny_matrix = Matrix(self.isogeny_matrix)
        self.one_deg = ZZ(self.class_deg).is_prime()

        # Create isogeny graph:
        self.graph = make_graph(self.isogeny_matrix)
        P = self.graph.plot(edge_labels=True)
        self.graph_img = encode_plot(P)
        self.graph_link = '<img src="%s" width="200" height="150"/>' % self.graph_img
        self.isogeny_matrix_str = latex(Matrix(self.isogeny_matrix))

        self.field = FIELD(self.field_label)
        self.field_name = field_pretty(self.field_label)
        self.field_knowl = nf_display_knowl(self.field_label,
                                            lmfdb.base.getDBConnection(),
                                            self.field_name)

        def curve_url(c):
            return url_for(".show_ecnf",
                           nf=c['field_label'],
                           conductor_label=c['conductor_label'],
                           class_label=c['iso_label'],
                           number=c['number'])

        self.curves = [[
            c['short_label'],
            curve_url(c),
            web_ainvs(self.field_label, c['ainvs'])
        ] for c in self.db_curves]

        self.urls = {}
        self.urls['class'] = url_for(".show_ecnf_isoclass",
                                     nf=self.field_label,
                                     conductor_label=self.conductor_label,
                                     class_label=self.iso_label)
        self.urls['conductor'] = url_for(".show_ecnf_conductor",
                                         nf=self.field_label,
                                         conductor_label=self.conductor_label)
        self.urls['field'] = url_for('.show_ecnf1', nf=self.field_label)
        sig = self.signature
        totally_real = sig[1] == 0
        imag_quadratic = sig == [0, 1]
        if totally_real:
            self.hmf_label = "-".join(
                [self.field_label, self.conductor_label, self.iso_label])
            self.urls['hmf'] = url_for('hmf.render_hmf_webpage',
                                       field_label=self.field_label,
                                       label=self.hmf_label)
            if sig[0] <= 2:
                self.urls['Lfunction'] = url_for(
                    "l_functions.l_function_ecnf_page",
                    field_label=self.field_label,
                    conductor_label=self.conductor_label,
                    isogeny_class_label=self.iso_label)
            elif self.abs_disc**2 * self.conductor_norm < 40000:
                # we shouldn't trust the Lfun computed on the fly for large conductor
                self.urls['Lfunction'] = url_for(
                    "l_functions.l_function_hmf_page",
                    field=self.field_label,
                    label=self.hmf_label,
                    character='0',
                    number='0')

        if imag_quadratic:
            self.bmf_label = "-".join(
                [self.field_label, self.conductor_label, self.iso_label])
            self.bmf_url = url_for('bmf.render_bmf_webpage',
                                   field_label=self.field_label,
                                   level_label=self.conductor_label,
                                   label_suffix=self.iso_label)
            self.urls['Lfunction'] = url_for(
                "l_functions.l_function_ecnf_page",
                field_label=self.field_label,
                conductor_label=self.conductor_label,
                isogeny_class_label=self.iso_label)

        self.friends = []
        if totally_real:
            self.friends += [('Hilbert Modular Form ' + self.hmf_label,
                              self.urls['hmf'])]

        if imag_quadratic:
            #self.friends += [('Bianchi Modular Form %s not available' % self.bmf_label, '')]
            self.friends += [('Bianchi Modular Form %s' % self.bmf_label,
                              self.bmf_url)]

        if 'Lfunction' in self.urls:
            self.friends += [('L-function', self.urls['Lfunction'])]
        else:
            self.friends += [('L-function not available', "")]

        self.properties = [('Base field', self.field_name),
                           ('Label', self.class_label),
                           (None, self.graph_link),
                           ('Conductor', '%s' % self.conductor_label)]
        if self.rk != '?':
            self.properties += [('Rank', '%s' % self.rk)]
        else:
            if self.rk_bnds == 'not recorded':
                self.properties += [('Rank', '%s' % self.rk_bnds)]
            else:
                self.properties += [('Rank bounds', '%s' % self.rk_bnds)]

        self.bread = [('Elliptic Curves ', url_for(".index")),
                      (self.field_label, self.urls['field']),
                      (self.conductor_label, self.urls['conductor']),
                      ('isogeny class %s' % self.short_label,
                       self.urls['class'])]
示例#18
0
    def make_class(self):

        # Create a list of the curves in the class from the database
        self.db_curves = [c for c in db_ecnf().find(
            {'field_label': self.field_label, 'conductor_norm':
             self.conductor_norm, 'conductor_label':
             self.conductor_label, 'iso_nlabel': self.iso_nlabel}).sort('number')]

        # Rank or bounds
        try:
            self.rk = web_latex(self.db_curves[0]['rank'])
        except KeyError:
            self.rk = "?"
        try:
            self.rk_bnds = "%s...%s" % tuple(self.db_curves[0]['rank_bounds'])
        except KeyError:
            self.rank_bounds = [0, sage.rings.infinity.Infinity]
            self.rk_bnds = "not recorded"


        # Extract the isogeny degree matrix from the database if possible, else create it
        if hasattr(self, 'isogeny_matrix'):
            from sage.matrix.all import Matrix
            self.isogeny_matrix = Matrix(self.isogeny_matrix)
        else:
            self.isogeny_matrix = make_iso_matrix(self.db_curves)

        # Create isogeny graph:
        self.graph = make_graph(self.isogeny_matrix)
        P = self.graph.plot(edge_labels=True)
        self.graph_img = encode_plot(P)
        self.graph_link = '<img src="%s" width="200" height="150"/>' % self.graph_img
        self.isogeny_matrix_str = latex(matrix(self.isogeny_matrix))

        self.field = field_pretty(self.field_label)
        self.field_knowl = nf_display_knowl(self.field_label, lmfdb.base.getDBConnection(), self.field)
        def curve_url(c):
            return url_for(".show_ecnf",
                           nf=c['field_label'],
                           conductor_label=c['conductor_label'],
                           class_label=c['iso_label'],
                           number=c['number'])

        self.curves = [[c['short_label'], curve_url(c), web_ainvs(self.field_label,c['ainvs'])] for c in self.db_curves]

        self.urls = {}
        self.urls['class'] = url_for(".show_ecnf_isoclass", nf=self.field_label, conductor_label=self.conductor_label, class_label=self.iso_label)
        self.urls['conductor'] = url_for(".show_ecnf_conductor", nf=self.field_label, conductor_label=self.conductor_label)
        self.urls['field'] = url_for('.show_ecnf1', nf=self.field_label)
        sig = self.signature
        totally_real = sig[1] == 0
        imag_quadratic = sig == [0,1]
        if totally_real:
            self.hmf_label = "-".join([self.field_label, self.conductor_label, self.iso_label])
            self.urls['hmf'] = url_for('hmf.render_hmf_webpage', field_label=self.field_label, label=self.hmf_label)
            self.urls['Lfunction'] = url_for("l_functions.l_function_hmf_page", field=self.field_label, label=self.hmf_label, character='0', number='0')

        if imag_quadratic:
            self.bmf_label = "-".join([self.field_label, self.conductor_label, self.iso_label])

        self.friends = []
        if totally_real:
            self.friends += [('Hilbert Modular Form ' + self.hmf_label, self.urls['hmf'])]
            self.friends += [('L-function', self.urls['Lfunction'])]
        if imag_quadratic:
            self.friends += [('Bianchi Modular Form %s not available' % self.bmf_label, '')]

        self.properties = [('Base field', self.field),
                           ('Label', self.class_label),
                           (None, self.graph_link),
                           ('Conductor', '%s' % self.conductor_label)
                       ]
        if self.rk != '?':
            self.properties += [('Rank', '%s' % self.rk)]
        else:
            if self.rk_bnds == 'not recorded':
                self.properties += [('Rank', '%s' % self.rk_bnds)]
            else:
                self.properties += [('Rank bounds', '%s' % self.rk_bnds)]

        self.bread = [('Elliptic Curves ', url_for(".index")),
                      (self.field_label, self.urls['field']),
                      (self.conductor_label, self.urls['conductor']),
                      ('isogeny class %s' % self.short_label, self.urls['class'])]
示例#19
0
文件: main.py 项目: akoutsianas/lmfdb
def download_search(info):
    dltype = info['Submit']
    delim = 'bracket'
    com = r'\\'  # single line comment start
    com1 = ''  # multiline comment start
    com2 = ''  # multiline comment end
    filename = 'elliptic_curves.gp'
    mydate = time.strftime("%d %B %Y")
    if dltype == 'sage':
        com = '#'
        filename = 'elliptic_curves.sage'
    if dltype == 'magma':
        com = ''
        com1 = '/*'
        com2 = '*/'
        delim = 'magma'
        filename = 'elliptic_curves.m'
    s = com1 + "\n"
    s += com + ' Elliptic curves downloaded from the LMFDB downloaded on %s.\n'%(mydate)
    s += com + ' Below is a list called data. Each entry has the form:\n'
    s += com + '   [[field_poly],[Weierstrass Coefficients, constant first in increasing degree]]\n'
    s += '\n' + com2
    s += '\n'
    
    if dltype == 'magma':
        s += 'P<x> := PolynomialRing(Rationals()); \n'
        s += 'data := ['
    elif dltype == 'sage':
        s += 'x = polygen(QQ) \n'
        s += 'data = [ '
    else:
        s += 'data = [ '
    s += '\\\n'
    nf_dict = {}
    res = db_ecnf().find(ast.literal_eval(info["query"]))
    for f in res:
        nf = str(f['field_label'])
        # look up number field and see if we already have the min poly
        if nf in nf_dict:
            poly = nf_dict[nf]
        else:
            poly = str(WebNumberField(f['field_label']).poly())
            nf_dict[nf] = poly
        entry = str(f['ainvs'])
        entry = entry.replace('u','')
        entry = entry.replace('\'','')
        s += '[[' + poly + '], ' + entry + '],\\\n'
    s = s[:-3]
    s += ']\n'
    if delim == 'brace':
        s = s.replace('[', '{')
        s = s.replace(']', '}')
    if delim == 'magma':
        s = s.replace('[', '[*')
        s = s.replace(']', '*]')
        s += ';'
    strIO = StringIO.StringIO()
    strIO.write(s)
    strIO.seek(0)
    return send_file(strIO,
                     attachment_filename=filename,
                     as_attachment=True)
示例#20
0
def download_search(info):
    dltype = info['Submit']
    delim = 'bracket'
    com = r'\\'  # single line comment start
    com1 = ''  # multiline comment start
    com2 = ''  # multiline comment end
    filename = 'elliptic_curves.gp'
    mydate = time.strftime("%d %B %Y")
    if dltype == 'sage':
        com = '#'
        filename = 'elliptic_curves.sage'
    if dltype == 'magma':
        com = ''
        com1 = '/*'
        com2 = '*/'
        delim = 'magma'
        filename = 'elliptic_curves.m'
    s = com1 + "\n"
    s += com + ' Elliptic curves downloaded from the LMFDB downloaded on %s.\n' % (
        mydate)
    s += com + ' Below is a list called data. Each entry has the form:\n'
    s += com + '   [[field_poly],[Weierstrass Coefficients, constant first in increasing degree]]\n'
    s += '\n' + com2
    s += '\n'

    if dltype == 'magma':
        s += 'P<x> := PolynomialRing(Rationals()); \n'
        s += 'data := ['
    elif dltype == 'sage':
        s += 'x = polygen(QQ) \n'
        s += 'data = [ '
    else:
        s += 'data = [ '
    s += '\\\n'
    nf_dict = {}
    res = db_ecnf().find(ast.literal_eval(info["query"]))
    for f in res:
        nf = str(f['field_label'])
        # look up number field and see if we already have the min poly
        if nf in nf_dict:
            poly = nf_dict[nf]
        else:
            poly = str(WebNumberField(f['field_label']).poly())
            nf_dict[nf] = poly
        entry = str(f['ainvs'])
        entry = entry.replace('u', '')
        entry = entry.replace('\'', '')
        entry = entry.replace(';', '],[')
        s += '[[' + poly + '], [[' + entry + ']]],\\\n'
    s = s[:-3]
    s += ']\n'

    if delim == 'brace':
        s = s.replace('[', '{')
        s = s.replace(']', '}')
    if delim == 'magma':
        s = s.replace('[', '[*')
        s = s.replace(']', '*]')
        s += ';'
    strIO = StringIO.StringIO()
    strIO.write(s)
    strIO.seek(0)
    return send_file(strIO,
                     attachment_filename=filename,
                     as_attachment=True,
                     add_etags=False)
示例#21
0
文件: main.py 项目: fredstro/lmfdb
def elliptic_curve_search(**args):
    info = to_dict(args["data"])

    if "download" in info and info["download"] != 0:
        return download_search(info)

    if not "query" in info:
        info["query"] = {}

    bread = [("Elliptic Curves", url_for(".index")), ("Search Results", ".")]
    if "jump" in info:
        label = info.get("label", "").replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label.strip())
        except ValueError:
            info["err"] = ""
            return search_input_error(info, bread)

        return show_ecnf(nf, cond_label, iso_label, number)

    query = {}

    try:
        parse_ints(info, query, "conductor_norm")
        parse_noop(info, query, "conductor_label")
        parse_nf_string(info, query, "field", name="base number field", qfield="field_label")
        parse_nf_elt(info, query, "jinv", name="j-invariant")
        parse_ints(info, query, "torsion", name="Torsion order", qfield="torsion_order")
        parse_bracketed_posints(info, query, "torsion_structure", maxlength=2)
        if "torsion_structure" in query and not "torsion_order" in query:
            query["torsion_order"] = reduce(mul, [int(n) for n in query["torsion_structure"]], 1)
    except ValueError:
        return search_input_error(info, bread)

    if "include_isogenous" in info and info["include_isogenous"] == "off":
        info["number"] = 1
        query["number"] = 1

    if "include_base_change" in info and info["include_base_change"] == "off":
        query["base_change"] = []
    else:
        info["include_base_change"] = "on"

    if "include_Q_curves" in info:
        if info["include_Q_curves"] == "exclude":
            query["q_curve"] = False
        elif info["include_Q_curves"] == "only":
            query["q_curve"] = True

    if "include_cm" in info:
        if info["include_cm"] == "exclude":
            query["cm"] = 0
        elif info["include_cm"] == "only":
            query["cm"] = {"$ne": 0}

    info["query"] = query
    count = parse_count(info, 50)
    start = parse_start(info)

    # make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if start >= nres:
        start -= (1 + (start - nres) / count) * count
    if start < 0:
        start = 0

    res = (
        cursor.sort(
            [
                ("field_label", ASC),
                ("conductor_norm", ASC),
                ("conductor_label", ASC),
                ("iso_nlabel", ASC),
                ("number", ASC),
            ]
        )
        .skip(start)
        .limit(count)
    )

    res = list(res)
    for e in res:
        e["numb"] = str(e["number"])
        e["field_knowl"] = nf_display_knowl(e["field_label"], getDBConnection(), field_pretty(e["field_label"]))

    info["curves"] = res  # [ECNF(e) for e in res]
    info["number"] = nres
    info["start"] = start
    info["count"] = count
    info["more"] = int(start + count < nres)
    info["field_pretty"] = field_pretty
    info["web_ainvs"] = web_ainvs
    if nres == 1:
        info["report"] = "unique match"
    else:
        if nres > count or start != 0:
            info["report"] = "displaying matches %s-%s of %s" % (start + 1, min(nres, start + count), nres)
        else:
            info["report"] = "displaying all %s matches" % nres
    t = "Elliptic Curve search results"
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#22
0
文件: main.py 项目: sibilant/lmfdb
def elliptic_curve_search(**args):
    info = to_dict(args['data'])
    if 'jump' in info:
        label = info.get('label', '').replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label)
        except IndexError:
            if not 'query' in info:
                info['query'] = {}
            bread = [("Elliptic Curves", url_for(".index"))]
            info['err'] = 'No elliptic curve in the database has label %s.' % label
            return search_input_error(info, bread)

        return show_ecnf(nf, cond_label, iso_label, number)

    query = {}
    bread = [('Elliptic Curves', url_for(".index")),
             ('Search Results', '.')]

    if 'conductor_norm' in info:
        Nnorm = clean_input(info['conductor_norm'])
        Nnorm = Nnorm.replace('..', '-').replace(' ', '')
        tmp = parse_range2(Nnorm, 'conductor_norm')
        if tmp[0] == '$or' and '$or' in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query['$or']]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if 'conductor_label' in info:
        query['conductor_label'] = info['conductor_label']

    if 'jinv' in info:
        query['jinv'] = info['jinv']

    if info.get('torsion'):
        ran = info['torsion'] = clean_input(info['torsion'])
        ran = ran.replace('..', '-').replace(' ', '')
        if not LIST_RE.match(ran):
            info['err'] = 'Error parsing input for the torsion order.  It needs to be an integer (such as 5), a range of integers (such as 2-10 or 2..10), or a comma-separated list of these (such as 4,9,16 or 4-25, 81-121).'
            return search_input_error(info, bread)
        # Past input check
        tmp = parse_range2(ran, 'torsion_order')
        # work around syntax for $or
        # we have to foil out multiple or conditions
        if tmp[0] == '$or' and '$or' in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query['$or']]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if 'torsion_structure' in info and info['torsion_structure']:
        info['torsion_structure'] = clean_input(info['torsion_structure'])
        if not TORS_RE.match(info['torsion_structure']):
            info['err'] = 'Error parsing input for the torsion structure.  It needs to be one or more integers in square brackets, such as [6], [2,2], or [2,4].  Moreover, each integer should be bigger than 1, and each divides the next.'
            return search_input_error(info, bread)
        query['torsion_structure'] = parse_list(info['torsion_structure'])

    if 'include_isogenous' in info and info['include_isogenous'] == 'off':
        query['number'] = 1

    if 'include_base_change' in info and info['include_base_change'] == 'off':
        query['base_change'] = []
    else:
        info['include_base_change'] = "on"

    if 'field' in info:
        query['field_label'] = parse_field_string(info['field'])

    info['query'] = query

# process count and start if not default:

    count_default = 50
    if info.get('count'):
        try:
            count = int(info['count'])
        except:
            count = count_default
    else:
        count = count_default

    start_default = 0
    if info.get('start'):
        try:
            start = int(info['start'])
            if(start < 0):
                start += (1 - (start + 1) / count) * count
        except:
            start = start_default
    else:
        start = start_default

# make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if(start >= nres):
        start -= (1 + (start - nres) / count) * count
    if(start < 0):
        start = 0
    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC), ('conductor_label', ASC), ('iso_label', ASC), ('number', ASC)]).skip(start).limit(count)

    res = list(res)
    for e in res:
        e['numb'] = str(e['number'])
        e['field_knowl'] = nf_display_knowl(e['field_label'], getDBConnection(), e['field_label'])

    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curve search results'
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#23
0
    def make_class(self):

        # Create a list of the curves in the class from the database
        self.db_curves = [c for c in db_ecnf().find(
            {'field_label': self.field_label, 'conductor_norm':
             self.conductor_norm, 'conductor_label':
             self.conductor_label, 'iso_nlabel': self.iso_nlabel}).sort('number')]

        # Rank or bounds
        try:
            self.rk = web_latex(self.db_curves[0]['rank'])
        except KeyError:
            self.rk = "?"
        try:
            self.rk_bnds = "%s...%s" % tuple(self.db_curves[0]['rank_bounds'])
        except KeyError:
            self.rank_bounds = [0, Infinity]
            self.rk_bnds = "not recorded"


        # Extract the isogeny degree matrix from the database
        if not hasattr(self, 'isogeny_matrix'):
            # this would happen if the class is initiated with a curve
            # which is not #1 in its class:
            self.isogeny_matrix = self.db_curves[0].isogeny_matrix
        self.isogeny_matrix = Matrix(self.isogeny_matrix)
        self.one_deg = ZZ(self.class_deg).is_prime()

        # Create isogeny graph:
        self.graph = make_graph(self.isogeny_matrix)
        P = self.graph.plot(edge_labels=True)
        self.graph_img = encode_plot(P)
        self.graph_link = '<img src="%s" width="200" height="150"/>' % self.graph_img
        self.isogeny_matrix_str = latex(Matrix(self.isogeny_matrix))

        self.field = FIELD(self.field_label)
        self.field_name = field_pretty(self.field_label)
        self.field_knowl = nf_display_knowl(self.field_label, lmfdb.base.getDBConnection(), self.field_name)
        def curve_url(c):
            return url_for(".show_ecnf",
                           nf=c['field_label'],
                           conductor_label=c['conductor_label'],
                           class_label=c['iso_label'],
                           number=c['number'])

        self.curves = [[c['short_label'], curve_url(c), web_ainvs(self.field_label,c['ainvs'])] for c in self.db_curves]

        self.urls = {}
        self.urls['class'] = url_for(".show_ecnf_isoclass", nf=self.field_label, conductor_label=self.conductor_label, class_label=self.iso_label)
        self.urls['conductor'] = url_for(".show_ecnf_conductor", nf=self.field_label, conductor_label=self.conductor_label)
        self.urls['field'] = url_for('.show_ecnf1', nf=self.field_label)
        sig = self.signature
        totally_real = sig[1] == 0
        imag_quadratic = sig == [0,1]
        if totally_real:
            self.hmf_label = "-".join([self.field_label, self.conductor_label, self.iso_label])
            self.urls['hmf'] = url_for('hmf.render_hmf_webpage', field_label=self.field_label, label=self.hmf_label)
            if sig[0] <= 2:
                self.urls['Lfunction'] = url_for("l_functions.l_function_ecnf_page", field_label=self.field_label, conductor_label=self.conductor_label, isogeny_class_label=self.iso_label)
            elif self.abs_disc ** 2 * self.conductor_norm < 40000:
                # we shouldn't trust the Lfun computed on the fly for large conductor
                self.urls['Lfunction'] = url_for("l_functions.l_function_hmf_page", field=self.field_label, label=self.hmf_label, character='0', number='0')

        if imag_quadratic:
            self.bmf_label = "-".join([self.field_label, self.conductor_label, self.iso_label])
            self.bmf_url = url_for('bmf.render_bmf_webpage', field_label=self.field_label, level_label=self.conductor_label, label_suffix=self.iso_label)
            self.urls['Lfunction'] = url_for("l_functions.l_function_ecnf_page", field_label=self.field_label, conductor_label=self.conductor_label, isogeny_class_label=self.iso_label)

        self.friends = []
        if totally_real:
            self.friends += [('Hilbert Modular Form ' + self.hmf_label, self.urls['hmf'])]

        if imag_quadratic:
            #self.friends += [('Bianchi Modular Form %s not available' % self.bmf_label, '')]
            self.friends += [('Bianchi Modular Form %s' % self.bmf_label, self.bmf_url)]

        if 'Lfunction' in self.urls:
            self.friends += [('L-function', self.urls['Lfunction'])]
        else:
            self.friends += [('L-function not available', "")]


        self.properties = [('Base field', self.field_name),
                           ('Label', self.class_label),
                           (None, self.graph_link),
                           ('Conductor', '%s' % self.conductor_label)
                       ]
        if self.rk != '?':
            self.properties += [('Rank', '%s' % self.rk)]
        else:
            if self.rk_bnds == 'not recorded':
                self.properties += [('Rank', '%s' % self.rk_bnds)]
            else:
                self.properties += [('Rank bounds', '%s' % self.rk_bnds)]

        self.bread = [('Elliptic Curves ', url_for(".index")),
                      (self.field_label, self.urls['field']),
                      (self.conductor_label, self.urls['conductor']),
                      ('isogeny class %s' % self.short_label, self.urls['class'])]
示例#24
0
def random_curve():
    from sage.misc.prandom import randint
    n = get_stats().counts()['ncurves']
    n = randint(0,n-1)
    E = db_ecnf().find()[n]
    return redirect(url_for(".show_ecnf", nf=E['field_label'], conductor_label=E['conductor_label'], class_label=E['iso_label'], number=E['number']), 301)
示例#25
0
def elliptic_curve_search(**args):
    info = to_dict(args["data"])
    if "jump" in info:
        label = info.get("label", "").replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        label_parts = label.split("-", 2)
        nf = label_parts[0]
        cond_label = label_parts[1]
        cur_label = label_parts[2]
        return show_ecnf(nf, cond_label, cur_label)  ##!!!

    query = {}

    if "conductor_norm" in info:
        Nnorm = clean_input(info["conductor_norm"])
        Nnorm = Nnorm.replace("..", "-").replace(" ", "")
        tmp = parse_range2(Nnorm, "conductor_norm")
        if tmp[0] == "$or" and "$or" in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query["$or"]]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if "conductor_label" in info:
        query["conductor_label"] = info["conductor_label"]

    if "include_isogenous" in info and info["include_isogenous"] == "off":
        query["number"] = 1

    if "field" in info:
        query["field_label"] = info["field"]

    info["query"] = query

    # process count and start if not default:

    count_default = 50
    if info.get("count"):
        try:
            count = int(info["count"])
        except:
            count = count_default
    else:
        count = count_default

    start_default = 0
    if info.get("start"):
        try:
            start = int(info["start"])
            if start < 0:
                start += (1 - (start + 1) / count) * count
        except:
            start = start_default
    else:
        start = start_default

    # make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if start >= nres:
        start -= (1 + (start - nres) / count) * count
    if start < 0:
        start = 0
    res = (
        cursor.sort(
            [
                ("field_label", ASC),
                ("conductor_norm", ASC),
                ("conductor_label", ASC),
                ("iso_label", ASC),
                ("number", ASC),
            ]
        )
        .skip(start)
        .limit(count)
    )

    bread = [("Elliptic Curves", url_for(".index")), ("Search Results", ".")]

    res = list(res)
    for e in res:
        e["numb"] = str(e["number"])
        e["field_knowl"] = nf_display_knowl(e["field_label"], getDBConnection(), e["field_label"])

    info["curves"] = res  # [ECNF(e) for e in res]
    info["number"] = nres
    info["start"] = start
    info["count"] = count
    info["more"] = int(start + count < nres)
    info["field_pretty"] = field_pretty
    info["web_ainvs"] = web_ainvs
    if nres == 1:
        info["report"] = "unique match"
    else:
        if nres > count or start != 0:
            info["report"] = "displaying matches %s-%s of %s" % (start + 1, min(nres, start + count), nres)
        else:
            info["report"] = "displaying all %s matches" % nres
    t = "Elliptic Curve search results"
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#26
0
文件: main.py 项目: elguindy/lmfdb
def elliptic_curve_search(**args):
    info = to_dict(args['data'])
    if 'jump' in info:
        label = info.get('label', '').replace(" ", "")
        label_parts = label.split("-",1)
        nf = label_parts[0]
        label = label_parts[1]
        return show_ecnf(nf,label)

    query = {}

    if 'conductor_norm' in info:
        Nnorm = clean_input(info['conductor_norm'])
        Nnorm = Nnorm.replace('..', '-').replace(' ', '')
        tmp = parse_range2(Nnorm, 'conductor_norm')
        if tmp[0] == '$or' and '$or' in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query['$or']]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if 'include_isogenous' in info and info['include_isogenous'] == 'off':
        query['number'] = 1

    if 'field' in info:
        query['field_label'] = info['field']

    info['query'] = query

# process count and start if not default:

    count_default = 20
    if info.get('count'):
        try:
            count = int(info['count'])
        except:
            count = count_default
    else:
        count = count_default

    start_default = 0
    if info.get('start'):
        try:
            start = int(info['start'])
            if(start < 0):
                start += (1 - (start + 1) / count) * count
        except:
            start = start_default
    else:
        start = start_default

# make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if(start >= nres):
        start -= (1 + (start - nres) / count) * count
    if(start < 0):
        start = 0
    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC), ('conductor_label', ASC), ('iso_label', ASC), ('number', ASC)]).skip(start).limit(count)

    bread = []#[('Elliptic Curves over Number Fields', url_for(".elliptic_curve_search")),             ]
    bread = [('Elliptic Curves', url_for(".index")),
             ('Search Results', '.')]

    res = list(res)
    for e in res:
        e['field_knowl'] = nf_display_knowl(e['field_label'], getDBConnection(), e['field_label'])
    info['curves'] = res # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curve search results'
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#27
0
文件: main.py 项目: sfrechet/lmfdb
def elliptic_curve_search(**args):
    info = to_dict(args["data"])
    if "jump" in info:
        label = info.get("label", "").replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label)
        except IndexError:
            if not "query" in info:
                info["query"] = {}
            bread = [("Elliptic Curves", url_for(".index"))]
            info["err"] = "No elliptic curve in the database has label %s." % label
            return search_input_error(info, bread)

        return show_ecnf(nf, cond_label, iso_label, number)

    query = {}
    bread = [("Elliptic Curves", url_for(".index")), ("Search Results", ".")]

    if "conductor_norm" in info:
        Nnorm = clean_input(info["conductor_norm"])
        Nnorm = Nnorm.replace("..", "-").replace(" ", "")
        tmp = parse_range2(Nnorm, "conductor_norm")
        if tmp[0] == "$or" and "$or" in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query["$or"]]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if "conductor_label" in info:
        query["conductor_label"] = info["conductor_label"]

    if "jinv" in info:
        query["jinv"] = info["jinv"]

    if info.get("torsion"):
        ran = info["torsion"] = clean_input(info["torsion"])
        ran = ran.replace("..", "-").replace(" ", "")
        if not LIST_RE.match(ran):
            info[
                "err"
            ] = "Error parsing input for the torsion order.  It needs to be an integer (such as 5), a range of integers (such as 2-10 or 2..10), or a comma-separated list of these (such as 4,9,16 or 4-25, 81-121)."
            return search_input_error(info, bread)
        # Past input check
        tmp = parse_range2(ran, "torsion_order")
        # work around syntax for $or
        # we have to foil out multiple or conditions
        if tmp[0] == "$or" and "$or" in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query["$or"]]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if "torsion_structure" in info and info["torsion_structure"]:
        res = parse_torsion_structure(info["torsion_structure"], 2)
        if "Error" in res:
            info["err"] = res
            return search_input_error(info, bread)
        # update info for repeat searches
        info["torsion_structure"] = str(res).replace(" ", "")
        query["torsion_structure"] = [int(r) for r in res]

    if "include_isogenous" in info and info["include_isogenous"] == "off":
        query["number"] = 1

    if "include_base_change" in info and info["include_base_change"] == "off":
        query["base_change"] = []
    else:
        info["include_base_change"] = "on"

    if "field" in info:
        query["field_label"] = parse_field_string(info["field"])

    info["query"] = query

    # process count and start if not default:

    count_default = 50
    if info.get("count"):
        try:
            count = int(info["count"])
        except:
            count = count_default
    else:
        count = count_default

    start_default = 0
    if info.get("start"):
        try:
            start = int(info["start"])
            if start < 0:
                start += (1 - (start + 1) / count) * count
        except:
            start = start_default
    else:
        start = start_default

    # make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if start >= nres:
        start -= (1 + (start - nres) / count) * count
    if start < 0:
        start = 0
    res = (
        cursor.sort(
            [
                ("field_label", ASC),
                ("conductor_norm", ASC),
                ("conductor_label", ASC),
                ("iso_label", ASC),
                ("number", ASC),
            ]
        )
        .skip(start)
        .limit(count)
    )

    res = list(res)
    for e in res:
        e["numb"] = str(e["number"])
        e["field_knowl"] = nf_display_knowl(e["field_label"], getDBConnection(), e["field_label"])

    info["curves"] = res  # [ECNF(e) for e in res]
    info["number"] = nres
    info["start"] = start
    info["count"] = count
    info["more"] = int(start + count < nres)
    info["field_pretty"] = field_pretty
    info["web_ainvs"] = web_ainvs
    if nres == 1:
        info["report"] = "unique match"
    else:
        if nres > count or start != 0:
            info["report"] = "displaying matches %s-%s of %s" % (start + 1, min(nres, start + count), nres)
        else:
            info["report"] = "displaying all %s matches" % nres
    t = "Elliptic Curve search results"
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#28
0
def elliptic_curve_search(info):

    if info.get('download') == '1' and info.get('Submit') and info.get(
            'query'):
        return download_search(info)

    if not 'query' in info:
        info['query'] = {}

    bread = info.get('bread', [('Elliptic Curves', url_for(".index")),
                               ('Search Results', '.')])
    if 'jump' in info:
        label = info.get('label', '').replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label.strip())
        except ValueError:
            info['err'] = ''
            return search_input_error(info, bread)

        return redirect(
            url_for(".show_ecnf",
                    nf=nf,
                    conductor_label=cond_label,
                    class_label=iso_label,
                    number=number), 301)

    query = {}

    if 'jinv' in info:
        if info.get('field', '').strip() == '2.2.5.1':
            info['jinv'] = info['jinv'].replace('phi', 'a')
        if info.get('field', '').strip() == '2.0.4.1':
            info['jinv'] = info['jinv'].replace('i', 'a')
    try:
        parse_ints(info, query, 'conductor_norm')
        parse_noop(info, query, 'conductor_label')
        parse_nf_string(info,
                        query,
                        'field',
                        name="base number field",
                        qfield='field_label')
        parse_nf_elt(info, query, 'jinv', name='j-invariant')
        parse_ints(info,
                   query,
                   'torsion',
                   name='Torsion order',
                   qfield='torsion_order')
        parse_bracketed_posints(info, query, 'torsion_structure', maxlength=2)
        if 'torsion_structure' in query and not 'torsion_order' in query:
            query['torsion_order'] = reduce(
                mul, [int(n) for n in query['torsion_structure']], 1)
        parse_ints(info, query, field='isodeg', qfield='isogeny_degrees')
    except (TypeError, ValueError):
        return search_input_error(info, bread)

    if query.get('jinv'):
        query['jinv'] = ','.join(query['jinv'])

    if query.get('field_label') == '1.1.1.1':
        return redirect(url_for("ec.rational_elliptic_curves", **request.args),
                        301)

    if 'include_isogenous' in info and info['include_isogenous'] == 'off':
        info['number'] = 1
        query['number'] = 1

    if 'include_base_change' in info and info['include_base_change'] == 'off':
        query['base_change'] = []
    else:
        info['include_base_change'] = "on"

    if 'include_Q_curves' in info:
        if info['include_Q_curves'] == 'exclude':
            query['q_curve'] = False
        elif info['include_Q_curves'] == 'only':
            query['q_curve'] = True

    if 'include_cm' in info:
        if info['include_cm'] == 'exclude':
            query['cm'] = 0
        elif info['include_cm'] == 'only':
            query['cm'] = {'$ne': 0}

    info['query'] = query
    count = parse_count(info, 50)
    start = parse_start(info)

    # make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if (start >= nres):
        start -= (1 + (start - nres) / count) * count
    if (start < 0):
        start = 0

    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC),
                       ('conductor_label', ASC), ('iso_nlabel', ASC),
                       ('number', ASC)]).skip(start).limit(count)

    res = list(res)
    for e in res:
        e['numb'] = str(e['number'])
        e['field_knowl'] = nf_display_knowl(e['field_label'],
                                            getDBConnection(),
                                            field_pretty(e['field_label']))

    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (
                start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = info.get('title', 'Elliptic Curve search results')
    return render_template("ecnf-search-results.html",
                           info=info,
                           credit=ecnf_credit,
                           bread=bread,
                           title=t)
示例#29
0
def render_hmf_webpage(**args):
    if 'data' in args:
        data = args['data']
        label = data['label']
    else:
        label = str(args['label'])
        data = get_hmf(label)
    if data is None:
        flash(Markup("Error: <span style='color:black'>%s</span> is not a valid Hilbert modular form label. It must be of the form (number field label) - (level label) - (orbit label) separated by dashes, such as 2.2.5.1-31.1-a" % args['label']), "error")
        return search_input_error()
    info = {}
    try:
        info['count'] = args['count']
    except KeyError:
        info['count'] = 10

    hmf_field = get_hmf_field(data['field_label'])
    gen_name = findvar(hmf_field['ideals'])
    nf = WebNumberField(data['field_label'], gen_name=gen_name)
    info['hmf_field'] = hmf_field
    info['field'] = nf
    info['base_galois_group'] = nf.galois_string()
    info['field_degree'] = nf.degree()
    info['field_disc'] = str(nf.disc())
    info['field_poly'] = teXify_pol(str(nf.poly()))

    info.update(data)

    info['downloads'] = [
        ('Download to Magma', url_for(".render_hmf_webpage_download", field_label=info['field_label'], label=info['label'], download_type='magma')),
        ('Download to Sage', url_for(".render_hmf_webpage_download", field_label=info['field_label'], label=info['label'], download_type='sage'))
        ]
    if hmf_field['narrow_class_no'] == 1 and nf.disc()**2 * data['level_norm'] < 40000:
        info['friends'] = [('L-function',
                            url_for("l_functions.l_function_hmf_page", field=info['field_label'], label=info['label'], character='0', number='0'))]
    else:
        info['friends'] = [('L-function not available', "")]
    if data['dimension'] == 1:   # Try to attach associated elliptic curve
        lab = split_class_label(info['label'])
        ec_from_hmf = db_ecnf().find_one({"label": label + '1'})
        if ec_from_hmf == None:
            info['friends'] += [('Elliptic curve not available', "")]
        else:
            info['friends'] += [('Isogeny class ' + info['label'], url_for("ecnf.show_ecnf_isoclass", nf=lab[0], conductor_label=lab[1], class_label=lab[2]))]

    bread = [("Modular Forms", url_for('mf.modular_form_main_page')), ('Hilbert Modular Forms', url_for(".hilbert_modular_form_render_webpage")),
        ('%s' % data['label'], ' ')]

    t = "Hilbert Cusp Form %s" % info['label']

    forms_space = db_forms().find(
        {'field_label': data['field_label'], 'level_ideal': data['level_ideal']},{'dimension':True})
    dim_space = 0
    for v in forms_space:
        dim_space += v['dimension']

    info['newspace_dimension'] = dim_space

    # Get hecke_polynomial, hecke_eigenvalues and AL_eigenvalues
    try:
        numeigs = request.args['numeigs']
        numeigs = int(numeigs)
    except:
        numeigs = 20
    info['numeigs'] = numeigs

    hecke_pol  = data['hecke_polynomial']
    eigs       = data['hecke_eigenvalues']
    eigs = eigs[:min(len(eigs), numeigs)]
    AL_eigs    = data['AL_eigenvalues']

    primes = hmf_field['primes']
    n = min(len(eigs), len(primes))
    info['eigs'] = [{'eigenvalue': add_space_if_positive(teXify_pol(eigs[i])),
                     'prime_ideal': teXify_pol(primes[i]),
                     'prime_norm': primes[i][1:primes[i].index(',')]} for i in range(n)]

    try:
        display_eigs = request.args['display_eigs']
        if display_eigs in ['True', 'true', '1', 'yes']:
            display_eigs = True
        else:
            display_eigs = False
    except KeyError:
        display_eigs = False

    if 'numeigs' in request.args:
        display_eigs = True

    info['hecke_polynomial'] = web_latex_split_on_pm(teXify_pol(hecke_pol))

    if not AL_eigs: # empty list
        if data['level_norm']==1: # OK, no bad primes
            info['AL_eigs'] = 'none'
        else:                     # not OK, AL eigs are missing
            info['AL_eigs'] = 'missing'
    else:
        info['AL_eigs'] = [{'eigenvalue': teXify_pol(al[1]),
                            'prime_ideal': teXify_pol(al[0]),
                            'prime_norm': al[0][1:al[0].index(',')]} for al in data['AL_eigenvalues']]

    max_eig_len = max([len(eig['eigenvalue']) for eig in info['eigs']])
    display_eigs = display_eigs or (max_eig_len<=300)
    info['display_eigs'] = display_eigs
    if not display_eigs:
        for eig in info['eigs']:
            if len(eig['eigenvalue']) > 300:
                eig['eigenvalue'] = '...'

    info['level_ideal'] = teXify_pol(info['level_ideal'])

    if 'is_CM' in data:
        is_CM = data['is_CM']
    else:
        is_CM = '?'
    info['is_CM'] = is_CM

    if 'is_base_change' in data:
        is_base_change = data['is_base_change']
    else:
        is_base_change = '?'
    info['is_base_change'] = is_base_change

    if 'q_expansions' in data:
        info['q_expansions'] = data['q_expansions']

    properties2 = [('Base field', '%s' % info['field'].field_pretty()),
                   ('Weight', '%s' % data['weight']),
                   ('Level norm', '%s' % data['level_norm']),
                   ('Level', '$' + teXify_pol(data['level_ideal']) + '$'),
                   ('Label', '%s' % data['label']),
                   ('Dimension', '%s' % data['dimension']),
                   ('CM', is_CM),
                   ('Base change', is_base_change)
                   ]

    return render_template("hilbert_modular_form.html", downloads=info["downloads"], info=info, properties2=properties2, credit=hmf_credit, title=t, bread=bread, friends=info['friends'], learnmore=learnmore_list())
示例#30
0
def render_hmf_webpage(**args):
    C = getDBConnection()
    if 'data' in args:
        data = args['data']
        label = data['label']
    else:
        label = str(args['label'])
        data = C.hmfs.forms.find_one({'label': label})
    if data is None:
        return "No such form"
    info = {}
    try:
        info['count'] = args['count']
    except KeyError:
        info['count'] = 10

    try:
        numeigs = request.args['numeigs']
        numeigs = int(numeigs)
    except:
        numeigs = 20

    hmf_field = C.hmfs.fields.find_one({'label': data['field_label']})
    gen_name = findvar(hmf_field['ideals'])
    nf = WebNumberField(data['field_label'], gen_name=gen_name)
    info['hmf_field'] = hmf_field
    info['field'] = nf
    info['base_galois_group'] = nf.galois_string()
    info['field_degree'] = nf.degree()
    info['field_disc'] = str(nf.disc())
    info['field_poly'] = teXify_pol(str(nf.poly()))

    info.update(data)

    info['downloads'] = [('Download to Magma',
                          url_for(".render_hmf_webpage_download",
                                  field_label=info['field_label'],
                                  label=info['label'],
                                  download_type='magma')),
                         ('Download to Sage',
                          url_for(".render_hmf_webpage_download",
                                  field_label=info['field_label'],
                                  label=info['label'],
                                  download_type='sage'))]
    if hmf_field['narrow_class_no'] == 1 and nf.disc(
    )**2 * data['level_norm'] < 40000:
        info['friends'] = [('L-function',
                            url_for("l_functions.l_function_hmf_page",
                                    field=info['field_label'],
                                    label=info['label'],
                                    character='0',
                                    number='0'))]
    else:
        info['friends'] = [('L-function not available', "")]
    if data['dimension'] == 1:  # Try to attach associated elliptic curve
        lab = split_class_label(info['label'])
        ec_from_hmf = db_ecnf().find_one({"label": label + '1'})
        if ec_from_hmf == None:
            info['friends'] += [('Elliptic curve not available', "")]
        else:
            info['friends'] += [('Isogeny class ' + info['label'],
                                 url_for("ecnf.show_ecnf_isoclass",
                                         nf=lab[0],
                                         conductor_label=lab[1],
                                         class_label=lab[2]))]

    bread = [('Hilbert Modular Forms',
              url_for(".hilbert_modular_form_render_webpage")),
             ('%s' % data['label'], ' ')]

    t = "Hilbert Cusp Form %s" % info['label']

    forms_space = C.hmfs.forms.find({
        'field_label': data['field_label'],
        'level_ideal': data['level_ideal']
    })
    dim_space = 0
    for v in forms_space:
        dim_space += v['dimension']

    info['newspace_dimension'] = dim_space

    w = polygen(QQ, 'w')
    e = polygen(QQ, 'e')
    eigs = data['hecke_eigenvalues']
    eigs = eigs[:min(len(eigs), numeigs)]

    primes = hmf_field['primes']
    n = min(len(eigs), len(primes))
    info['eigs'] = [{
        'eigenvalue': teXify_pol(eigs[i]),
        'prime_ideal': teXify_pol(primes[i]),
        'prime_norm': primes[i][1:primes[i].index(',')]
    } for i in range(n)]

    try:
        display_eigs = request.args['display_eigs']
        if display_eigs in ['True', 'true', '1', 'yes']:
            display_eigs = True
        else:
            display_eigs = False
    except KeyError:
        display_eigs = False

    if 'numeigs' in request.args:
        display_eigs = True

    info['hecke_polynomial'] = teXify_pol(info['hecke_polynomial'])

    if 'AL_eigenvalues_fixed' in data:
        if data['AL_eigenvalues_fixed'] == 'done':
            info['AL_eigs'] = [{
                'eigenvalue': teXify_pol(al[1]),
                'prime_ideal': teXify_pol(al[0]),
                'prime_norm': al[0][1:al[0].index(',')]
            } for al in data['AL_eigenvalues']]
        else:
            info['AL_eigs'] = [{'eigenvalue': '?', 'prime_ideal': '?'}]
    else:
        info['AL_eigs'] = [{'eigenvalue': '?', 'prime_ideal': '?'}]
    info['AL_eigs_count'] = len(info['AL_eigs']) != 0

    max_eig_len = max([len(eig['eigenvalue']) for eig in info['eigs']])
    display_eigs = display_eigs or (max_eig_len <= 300)
    if not display_eigs:
        for eig in info['eigs']:
            if len(eig['eigenvalue']) > 300:
                eig['eigenvalue'] = '...'
        for eig in info['AL_eigs']:
            if len(eig['eigenvalue']) > 300:
                eig['eigenvalue'] = '...'

    info['level_ideal'] = teXify_pol(info['level_ideal'])

    if 'is_CM' in data:
        is_CM = data['is_CM']
    else:
        is_CM = '?'
    info['is_CM'] = is_CM

    if 'is_base_change' in data:
        is_base_change = data['is_base_change']
    else:
        is_base_change = '?'
    info['is_base_change'] = is_base_change

    if 'q_expansions' in data:
        info['q_expansions'] = data['q_expansions']

    properties2 = [('Base field', '%s' % info['field'].field_pretty()),
                   ('Weight', '%s' % data['weight']),
                   ('Level norm', '%s' % data['level_norm']),
                   ('Level', '$' + teXify_pol(data['level_ideal']) + '$'),
                   ('Label', '%s' % data['label']),
                   ('Dimension', '%s' % data['dimension']), ('CM', is_CM),
                   ('Base change', is_base_change)]

    return render_template("hilbert_modular_form.html",
                           downloads=info["downloads"],
                           info=info,
                           properties2=properties2,
                           credit=hmf_credit,
                           title=t,
                           bread=bread,
                           friends=info['friends'],
                           learnmore=learnmore_list())
示例#31
0
    def make_class(self):

        # Create a list of the curves in the class from the database
        self.db_curves = [
            c for c in db_ecnf().find({
                'field_label': self.field_label,
                'conductor_norm': self.conductor_norm,
                'conductor_label': self.conductor_label,
                'iso_nlabel': self.iso_nlabel
            }).sort('number')
        ]

        # Rank or bounds
        try:
            self.rk = web_latex(self.db_curves[0]['rank'])
        except KeyError:
            self.rk = "?"
        try:
            self.rk_bnds = "%s...%s" % tuple(self.db_curves[0]['rank_bounds'])
        except KeyError:
            self.rank_bounds = [0, sage.rings.infinity.Infinity]
            self.rk_bnds = "not recorded"

        # Extract the isogeny degree matrix from the database if possible, else create it
        if hasattr(self, 'isogeny_matrix'):
            from sage.matrix.all import Matrix
            self.isogeny_matrix = Matrix(self.isogeny_matrix)
        else:
            self.isogeny_matrix = make_iso_matrix(self.db_curves)

        # Create isogeny graph:
        self.graph = make_graph(self.isogeny_matrix)
        P = self.graph.plot(edge_labels=True)
        self.graph_img = encode_plot(P)
        self.graph_link = '<img src="%s" width="200" height="150"/>' % self.graph_img
        self.isogeny_matrix_str = latex(matrix(self.isogeny_matrix))

        self.field = field_pretty(self.field_label)
        self.field_knowl = nf_display_knowl(self.field_label,
                                            lmfdb.base.getDBConnection(),
                                            self.field)

        def curve_url(c):
            return url_for(".show_ecnf",
                           nf=c['field_label'],
                           conductor_label=c['conductor_label'],
                           class_label=c['iso_label'],
                           number=c['number'])

        self.curves = [[
            c['short_label'],
            curve_url(c),
            web_ainvs(self.field_label, c['ainvs'])
        ] for c in self.db_curves]

        self.urls = {}
        self.urls['class'] = url_for(".show_ecnf_isoclass",
                                     nf=self.field_label,
                                     conductor_label=self.conductor_label,
                                     class_label=self.iso_label)
        self.urls['conductor'] = url_for(".show_ecnf_conductor",
                                         nf=self.field_label,
                                         conductor_label=self.conductor_label)
        self.urls['field'] = url_for('.show_ecnf1', nf=self.field_label)
        sig = self.signature
        totally_real = sig[1] == 0
        imag_quadratic = sig == [0, 1]
        if totally_real:
            self.hmf_label = "-".join(
                [self.field_label, self.conductor_label, self.iso_label])
            self.urls['hmf'] = url_for('hmf.render_hmf_webpage',
                                       field_label=self.field_label,
                                       label=self.hmf_label)
            self.urls['Lfunction'] = url_for("l_functions.l_function_hmf_page",
                                             field=self.field_label,
                                             label=self.hmf_label,
                                             character='0',
                                             number='0')

        if imag_quadratic:
            self.bmf_label = "-".join(
                [self.field_label, self.conductor_label, self.iso_label])

        self.friends = []
        if totally_real:
            self.friends += [('Hilbert Modular Form ' + self.hmf_label,
                              self.urls['hmf'])]
            self.friends += [('L-function', self.urls['Lfunction'])]
        if imag_quadratic:
            self.friends += [
                ('Bianchi Modular Form %s not available' % self.bmf_label, '')
            ]

        self.properties = [('Base field', self.field),
                           ('Label', self.class_label),
                           (None, self.graph_link),
                           ('Conductor', '%s' % self.conductor_label)]
        if self.rk != '?':
            self.properties += [('Rank', '%s' % self.rk)]
        else:
            if self.rk_bnds == 'not recorded':
                self.properties += [('Rank', '%s' % self.rk_bnds)]
            else:
                self.properties += [('Rank bounds', '%s' % self.rk_bnds)]

        self.bread = [('Elliptic Curves ', url_for(".index")),
                      (self.field_label, self.urls['field']),
                      (self.conductor_label, self.urls['conductor']),
                      ('isogeny class %s' % self.short_label,
                       self.urls['class'])]
示例#32
0
文件: main.py 项目: akoutsianas/lmfdb
def random_curve():
    E = random_object_from_collection(db_ecnf())
    return redirect(url_for(".show_ecnf", nf=E['field_label'], conductor_label=E['conductor_label'], class_label=E['iso_label'], number=E['number']), 301)
示例#33
0
def render_hmf_webpage(**args):
    if 'data' in args:
        data = args['data']
        label = data['label']
    else:
        label = str(args['label'])
        data = get_hmf(label)
    if data is None:
        flash(
            Markup(
                "Error: <span style='color:black'>%s</span> is not a valid Hilbert modular form label. It must be of the form (number field label) - (level label) - (orbit label) separated by dashes, such as 2.2.5.1-31.1-a"
                % args['label']), "error")
        return search_input_error()
    info = {}
    try:
        info['count'] = args['count']
    except KeyError:
        info['count'] = 10

    hmf_field = get_hmf_field(data['field_label'])
    gen_name = findvar(hmf_field['ideals'])
    nf = WebNumberField(data['field_label'], gen_name=gen_name)
    info['hmf_field'] = hmf_field
    info['field'] = nf
    info['base_galois_group'] = nf.galois_string()
    info['field_degree'] = nf.degree()
    info['field_disc'] = str(nf.disc())
    info['field_poly'] = teXify_pol(str(nf.poly()))

    info.update(data)

    info['downloads'] = [('Download to Magma',
                          url_for(".render_hmf_webpage_download",
                                  field_label=info['field_label'],
                                  label=info['label'],
                                  download_type='magma')),
                         ('Download to Sage',
                          url_for(".render_hmf_webpage_download",
                                  field_label=info['field_label'],
                                  label=info['label'],
                                  download_type='sage'))]
    if hmf_field['narrow_class_no'] == 1 and nf.disc(
    )**2 * data['level_norm'] < 40000:
        info['friends'] = [('L-function',
                            url_for("l_functions.l_function_hmf_page",
                                    field=info['field_label'],
                                    label=info['label'],
                                    character='0',
                                    number='0'))]
    else:
        info['friends'] = [('L-function not available', "")]
    if data['dimension'] == 1:  # Try to attach associated elliptic curve
        lab = split_class_label(info['label'])
        ec_from_hmf = db_ecnf().find_one({"label": label + '1'})
        if ec_from_hmf == None:
            info['friends'] += [('Elliptic curve not available', "")]
        else:
            info['friends'] += [('Isogeny class ' + info['label'],
                                 url_for("ecnf.show_ecnf_isoclass",
                                         nf=lab[0],
                                         conductor_label=lab[1],
                                         class_label=lab[2]))]

    bread = [('Hilbert Modular Forms',
              url_for(".hilbert_modular_form_render_webpage")),
             ('%s' % data['label'], ' ')]

    t = "Hilbert Cusp Form %s" % info['label']

    forms_space = db_search().find(
        {
            'field_label': data['field_label'],
            'level_ideal': data['level_ideal']
        }, {'dimension': True})
    dim_space = 0
    for v in forms_space:
        dim_space += v['dimension']

    info['newspace_dimension'] = dim_space

    # Get hecke_polynomial, hecke_eigenvalues and AL_eigenvalues
    try:
        numeigs = request.args['numeigs']
        numeigs = int(numeigs)
    except:
        numeigs = 20
    info['numeigs'] = numeigs

    hecke_pol = data['hecke_polynomial']
    eigs = data['hecke_eigenvalues']
    eigs = eigs[:min(len(eigs), numeigs)]
    AL_eigs = data['AL_eigenvalues']

    primes = hmf_field['primes']
    n = min(len(eigs), len(primes))
    info['eigs'] = [{
        'eigenvalue': teXify_pol(eigs[i]),
        'prime_ideal': teXify_pol(primes[i]),
        'prime_norm': primes[i][1:primes[i].index(',')]
    } for i in range(n)]

    try:
        display_eigs = request.args['display_eigs']
        if display_eigs in ['True', 'true', '1', 'yes']:
            display_eigs = True
        else:
            display_eigs = False
    except KeyError:
        display_eigs = False

    if 'numeigs' in request.args:
        display_eigs = True

    info['hecke_polynomial'] = web_latex_split_on_pm(teXify_pol(hecke_pol))

    if not AL_eigs:  # empty list
        if data['level_norm'] == 1:  # OK, no bad primes
            info['AL_eigs'] = 'none'
        else:  # not OK, AL eigs are missing
            info['AL_eigs'] = 'missing'
    else:
        info['AL_eigs'] = [{
            'eigenvalue': teXify_pol(al[1]),
            'prime_ideal': teXify_pol(al[0]),
            'prime_norm': al[0][1:al[0].index(',')]
        } for al in data['AL_eigenvalues']]

    max_eig_len = max([len(eig['eigenvalue']) for eig in info['eigs']])
    display_eigs = display_eigs or (max_eig_len <= 300)
    info['display_eigs'] = display_eigs
    if not display_eigs:
        for eig in info['eigs']:
            if len(eig['eigenvalue']) > 300:
                eig['eigenvalue'] = '...'

    info['level_ideal'] = teXify_pol(info['level_ideal'])

    if 'is_CM' in data:
        is_CM = data['is_CM']
    else:
        is_CM = '?'
    info['is_CM'] = is_CM

    if 'is_base_change' in data:
        is_base_change = data['is_base_change']
    else:
        is_base_change = '?'
    info['is_base_change'] = is_base_change

    if 'q_expansions' in data:
        info['q_expansions'] = data['q_expansions']

    properties2 = [('Base field', '%s' % info['field'].field_pretty()),
                   ('Weight', '%s' % data['weight']),
                   ('Level norm', '%s' % data['level_norm']),
                   ('Level', '$' + teXify_pol(data['level_ideal']) + '$'),
                   ('Label', '%s' % data['label']),
                   ('Dimension', '%s' % data['dimension']), ('CM', is_CM),
                   ('Base change', is_base_change)]

    return render_template("hilbert_modular_form.html",
                           downloads=info["downloads"],
                           info=info,
                           properties2=properties2,
                           credit=hmf_credit,
                           title=t,
                           bread=bread,
                           friends=info['friends'],
                           learnmore=learnmore_list())
示例#34
0
文件: main.py 项目: akoutsianas/lmfdb
def elliptic_curve_search(**args):
    info = to_dict(args['data'])
    
    if 'download' in info and info['download'] != 0:
        return download_search(info)

    if not 'query' in info:
        info['query'] = {}
    
    bread = [('Elliptic Curves', url_for(".index")),
             ('Search Results', '.')]
    if 'jump' in info:
        label = info.get('label', '').replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label.strip())
        except ValueError:
            info['err'] = ''
            return search_input_error(info, bread)

        return show_ecnf(nf, cond_label, iso_label, number)

    query = {}

    try:
        parse_ints(info,query,'conductor_norm')
        parse_noop(info,query,'conductor_label')
        parse_nf_string(info,query,'field',name="base number field",qfield='field_label')
        parse_nf_elt(info,query,'jinv',name='j-invariant')
        parse_ints(info,query,'torsion',name='Torsion order',qfield='torsion_order')
        parse_bracketed_posints(info,query,'torsion_structure',maxlength=2)
        if 'torsion_structure' in query and not 'torsion_order' in query:
            query['torsion_order'] = reduce(mul,[int(n) for n in query['torsion_structure']],1)
    except ValueError:
        return search_input_error(info, bread)

    if 'include_isogenous' in info and info['include_isogenous'] == 'off':
        info['number'] = 1
        query['number'] = 1

    if 'include_base_change' in info and info['include_base_change'] == 'off':
        query['base_change'] = []
    else:
        info['include_base_change'] = "on"

    if 'include_Q_curves' in info:
        if info['include_Q_curves'] == 'exclude':
            query['q_curve'] = False
        elif info['include_Q_curves'] == 'only':
            query['q_curve'] = True

    if 'include_cm' in info:
        if info['include_cm'] == 'exclude':
            query['cm'] = 0
        elif info['include_cm'] == 'only':
            query['cm'] = {'$ne' : 0}

    info['query'] = query
    count = parse_count(info, 50)
    start = parse_start(info)

    # make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if(start >= nres):
        start -= (1 + (start - nres) / count) * count
    if(start < 0):
        start = 0
    
    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC), ('conductor_label', ASC), ('iso_nlabel', ASC), ('number', ASC)]).skip(start).limit(count)

    res = list(res)
    for e in res:
        e['numb'] = str(e['number'])
        e['field_knowl'] = nf_display_knowl(e['field_label'], getDBConnection(), field_pretty(e['field_label']))

    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curve search results'
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)
示例#35
0
文件: main.py 项目: paulhus/lmfdb
def elliptic_curve_search(**args):
    info = to_dict(args['data'])
    if 'jump' in info:
        label = info.get('label', '').replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label.strip())
        except IndexError:
            if not 'query' in info:
                info['query'] = {}
            bread = [("Elliptic Curves", url_for(".index"))]
            info[
                'err'] = 'No elliptic curve in the database has label %s.' % label
            return search_input_error(info, bread)

        return show_ecnf(nf, cond_label, iso_label, number)

    query = {}
    bread = [('Elliptic Curves', url_for(".index")), ('Search Results', '.')]

    if 'conductor_norm' in info:
        Nnorm = clean_input(info['conductor_norm'])
        Nnorm = Nnorm.replace('..', '-').replace(' ', '')
        tmp = parse_range2(Nnorm, 'conductor_norm')
        if tmp[0] == '$or' and '$or' in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query['$or']]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if 'conductor_label' in info:
        query['conductor_label'] = info['conductor_label']

    if 'jinv' in info:
        query['jinv'] = info['jinv']

    if info.get('torsion'):
        ran = info['torsion'] = clean_input(info['torsion'])
        ran = ran.replace('..', '-').replace(' ', '')
        if not LIST_RE.match(ran):
            info[
                'err'] = 'Error parsing input for the torsion order.  It needs to be an integer (such as 5), a range of integers (such as 2-10 or 2..10), or a comma-separated list of these (such as 4,9,16 or 4-25, 81-121).'
            return search_input_error(info, bread)
        # Past input check
        tmp = parse_range2(ran, 'torsion_order')
        # work around syntax for $or
        # we have to foil out multiple or conditions
        if tmp[0] == '$or' and '$or' in query:
            newors = []
            for y in tmp[1]:
                oldors = [dict.copy(x) for x in query['$or']]
                for x in oldors:
                    x.update(y)
                newors.extend(oldors)
            tmp[1] = newors
        query[tmp[0]] = tmp[1]

    if 'torsion_structure' in info and info['torsion_structure']:
        res = parse_torsion_structure(info['torsion_structure'], 2)
        if 'Error' in res:
            info['err'] = res
            return search_input_error(info, bread)
        #update info for repeat searches
        info['torsion_structure'] = str(res).replace(' ', '')
        query['torsion_structure'] = [int(r) for r in res]

    if 'include_isogenous' in info and info['include_isogenous'] == 'off':
        query['number'] = 1

    if 'include_base_change' in info and info['include_base_change'] == 'off':
        query['base_change'] = []
    else:
        info['include_base_change'] = "on"

    if 'field' in info:
        query['field_label'] = parse_field_string(info['field'])

    info['query'] = query

    # process count and start if not default:

    count_default = 50
    if info.get('count'):
        try:
            count = int(info['count'])
        except:
            count = count_default
    else:
        count = count_default

    start_default = 0
    if info.get('start'):
        try:
            start = int(info['start'])
            if (start < 0):
                start += (1 - (start + 1) / count) * count
        except:
            start = start_default
    else:
        start = start_default


# make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if (start >= nres):
        start -= (1 + (start - nres) / count) * count
    if (start < 0):
        start = 0
    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC),
                       ('conductor_label', ASC), ('iso_nlabel', ASC),
                       ('number', ASC)]).skip(start).limit(count)

    res = list(res)
    for e in res:
        e['numb'] = str(e['number'])
        e['field_knowl'] = nf_display_knowl(e['field_label'],
                                            getDBConnection(),
                                            e['field_label'])

    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (
                start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curve search results'
    return render_template("ecnf-search-results.html",
                           info=info,
                           credit=ecnf_credit,
                           bread=bread,
                           title=t)
示例#36
0
def render_hmf_webpage(**args):
    C = getDBConnection()
    if 'data' in args:
        data = args['data']
        label = data['label']
    else:
        label = str(args['label'])
        data = C.hmfs.forms.find_one({'label': label})
    if data is None:
        return "No such form"
    info = {}
    try:
        info['count'] = args['count']
    except KeyError:
        info['count'] = 10

    try:
        numeigs = request.args['numeigs']
        numeigs = int(numeigs)
    except:
        numeigs = 20

    hmf_field = C.hmfs.fields.find_one({'label': data['field_label']})
    gen_name = findvar(hmf_field['ideals'])
    nf = WebNumberField(data['field_label'], gen_name=gen_name)
    info['field'] = nf
    info['base_galois_group'] = nf.galois_string()
    info['field_degree'] = nf.degree()
    info['field_disc'] = str(nf.disc())
    info['field_poly'] = teXify_pol(str(nf.poly()))

    info.update(data)

    info['downloads'] = [
        ('Download to Magma', url_for(".render_hmf_webpage_download", field_label=info['field_label'], label=info['label'], download_type='magma')),
        ('Download to Sage', url_for(".render_hmf_webpage_download", field_label=info['field_label'], label=info['label'], download_type='sage'))
        ]
    if hmf_field['narrow_class_no'] == 1:
        info['friends'] = [('L-function',
                            url_for("l_functions.l_function_hmf_page", field=info['field_label'], label=info['label'], character='0', number='0'))]
    else:
        info['friends'] = [('L-function not available', "")]
    if data['dimension'] == 1:   # Try to attach associated elliptic curve
        lab = split_class_label(info['label'])
        ec_from_hmf = db_ecnf().find_one({"label": label + '1'})
        if ec_from_hmf == None:
            info['friends'] += [('Elliptic curve not available', "")]
        else:
            info['friends'] += [('Isogeny class ' + info['label'], url_for("ecnf.show_ecnf_isoclass", nf=lab[0], conductor_label=lab[1], class_label=lab[2]))]

    bread = [('Hilbert Modular Forms', url_for(".hilbert_modular_form_render_webpage")), ('%s' % data[
                                                                                         'label'], ' ')]

    t = "Hilbert Cusp Form %s" % info['label']

    forms_space = C.hmfs.forms.find(
        {'field_label': data['field_label'], 'level_ideal': data['level_ideal']})
    dim_space = 0
    for v in forms_space:
        dim_space += v['dimension']

    info['newspace_dimension'] = dim_space

    w = polygen(QQ, 'w')
    e = polygen(QQ, 'e')
    eigs = data['hecke_eigenvalues']
    eigs = eigs[:min(len(eigs), numeigs)]

    primes = hmf_field['primes']
    n = min(len(eigs), len(primes))
    info['eigs'] = [{'eigenvalue': teXify_pol(eigs[i]),
                     'prime_ideal': teXify_pol(primes[i]),
                     'prime_norm': primes[i][1:primes[i].index(',')]} for i in range(n)]

    try:
        display_eigs = request.args['display_eigs']
        if display_eigs in ['True', 'true', '1', 'yes']:
            display_eigs = True
        else:
            display_eigs = False
    except KeyError:
        display_eigs = False

    if 'numeigs' in request.args:
        display_eigs = True

    info['hecke_polynomial'] = teXify_pol(info['hecke_polynomial'])

    if 'AL_eigenvalues_fixed' in data:
        if data['AL_eigenvalues_fixed'] == 'done':
            info['AL_eigs'] = [{'eigenvalue': teXify_pol(al[1]),
                                'prime_ideal': teXify_pol(al[0]),
                                'prime_norm': al[0][1:al[0].index(',')]} for al in data['AL_eigenvalues']]
        else:
            info['AL_eigs'] = [{'eigenvalue': '?', 'prime_ideal': '?'}]
    else:
        info['AL_eigs'] = [{'eigenvalue': '?', 'prime_ideal': '?'}]
    info['AL_eigs_count'] = len(info['AL_eigs']) != 0

    max_eig_len = max([len(eig['eigenvalue']) for eig in info['eigs']])
    display_eigs = display_eigs or (max_eig_len<=300)
    if not display_eigs:
        for eig in info['eigs']:
            if len(eig['eigenvalue']) > 300:
                eig['eigenvalue'] = '...'
        for eig in info['AL_eigs']:
            if len(eig['eigenvalue']) > 300:
                eig['eigenvalue'] = '...'

    info['level_ideal'] = teXify_pol(info['level_ideal'])

    if 'is_CM' in data:
        is_CM = data['is_CM']
    else:
        is_CM = '?'
    info['is_CM'] = is_CM

    if 'is_base_change' in data:
        is_base_change = data['is_base_change']
    else:
        is_base_change = '?'
    info['is_base_change'] = is_base_change

    if 'q_expansions' in data:
        info['q_expansions'] = data['q_expansions']

    properties2 = [('Base field', '%s' % info['field'].field_pretty()),
                   ('Weight', '%s' % data['weight']),
                   ('Level norm', '%s' % data['level_norm']),
                   ('Level', '$' + teXify_pol(data['level_ideal']) + '$'),
                   ('Label', '%s' % data['label_suffix']),
                   ('Dimension', '%s' % data['dimension']),
                   ('CM', is_CM),
                   ('Base change', is_base_change)
                   ]

    return render_template("hilbert_modular_form.html", downloads=info["downloads"], info=info, properties2=properties2, credit=hmf_credit, title=t, bread=bread, friends=info['friends'], learnmore=learnmore_list())
示例#37
0
def elliptic_curve_search(**args):
    info = to_dict(args['data'])
    
    if 'download' in info and info['download'] != 0:
        return download_search(info)
    
    bread = [('Elliptic Curves', url_for(".index")),
             ('Search Results', '.')]
    if 'jump' in info:
        label = info.get('label', '').replace(" ", "")
        # This label should be a full isogeny class label or a full
        # curve label (including the field_label component)
        try:
            nf, cond_label, iso_label, number = split_full_label(label.strip())
        except ValueError:
            if not 'query' in info:
                info['query'] = {}
            info['err'] = ''
            return search_input_error(info, bread)

        return show_ecnf(nf, cond_label, iso_label, number)

    query = {}

    try:
        parse_ints(info,query,'conductor_norm')
        parse_noop(info,query,'conductor_label')
        parse_nf_string(info,query,'field',name="base number field",qfield='field_label')
        parse_nf_elt(info,query,'jinv',name='j-invariant')
        parse_ints(info,query,'torsion',name='Torsion order',qfield='torsion_order')
        parse_bracketed_posints(info,query,'torsion_structure',maxlength=2)
    except ValueError:
        return search_input_error(info, bread)

    if 'include_isogenous' in info and info['include_isogenous'] == 'off':
        info['number'] = 1
        query['number'] = 1

    if 'include_base_change' in info and info['include_base_change'] == 'off':
        query['base_change'] = []
    else:
        info['include_base_change'] = "on"

    info['query'] = query
    count = parse_count(info, 50)
    start = parse_start(info)

    # make the query and trim results according to start/count:

    cursor = db_ecnf().find(query)
    nres = cursor.count()
    if(start >= nres):
        start -= (1 + (start - nres) / count) * count
    if(start < 0):
        start = 0
    
    res = cursor.sort([('field_label', ASC), ('conductor_norm', ASC), ('conductor_label', ASC), ('iso_nlabel', ASC), ('number', ASC)]).skip(start).limit(count)

    res = list(res)
    for e in res:
        e['numb'] = str(e['number'])
        e['field_knowl'] = nf_display_knowl(e['field_label'], getDBConnection(), field_pretty(e['field_label']))

    info['curves'] = res  # [ECNF(e) for e in res]
    info['number'] = nres
    info['start'] = start
    info['count'] = count
    info['more'] = int(start + count < nres)
    info['field_pretty'] = field_pretty
    info['web_ainvs'] = web_ainvs
    if nres == 1:
        info['report'] = 'unique match'
    else:
        if nres > count or start != 0:
            info['report'] = 'displaying matches %s-%s of %s' % (start + 1, min(nres, start + count), nres)
        else:
            info['report'] = 'displaying all %s matches' % nres
    t = 'Elliptic Curve search results'
    return render_template("ecnf-search-results.html", info=info, credit=ecnf_credit, bread=bread, title=t)