/+junk/pygooglechart-py3k

"""

PyGoogleChart - A complete Python wrapper for the Google Chart API

http://pygooglechart.slowchop.com/

Copyright 2007 Gerald Kaszuba

This program is free software: you can redistribute it and/or modify

it under the terms of the GNU General Public License as published by

the Free Software Foundation, either version 3 of the License, or

(at your option) any later version.

This program is distributed in the hope that it will be useful,

but WITHOUT ANY WARRANTY; without even the implied warranty of

MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the

GNU General Public License for more details.

You should have received a copy of the GNU General Public License

along with this program.  If not, see <http://www.gnu.org/licenses/>.

"""

import os

import urllib

import urllib2

import math

import random

import re

# Helper variables and functions

# -----------------------------------------------------------------------------

__version__ = '0.2.0'

reo_colour = re.compile('^([A-Fa-f0-9]{2,2}){3,4}$')

def _check_colour(colour):

    if not reo_colour.match(colour):

        raise InvalidParametersException('Colours need to be in ' \

            'RRGGBB or RRGGBBAA format. One of your colours has %s' % \

            colour)

# Exception Classes

# -----------------------------------------------------------------------------

class PyGoogleChartException(Exception):

    pass

class DataOutOfRangeException(PyGoogleChartException):

    pass

class UnknownDataTypeException(PyGoogleChartException):

    pass

class NoDataGivenException(PyGoogleChartException):

    pass

class InvalidParametersException(PyGoogleChartException):

    pass

class BadContentTypeException(PyGoogleChartException):

    pass

# Data Classes

# -----------------------------------------------------------------------------

class Data(object):

    def __init__(self, data):

        assert(type(self) != Data)  # This is an abstract class

        self.data = data

    @classmethod

    def float_scale_value(cls, value, range):

        lower, upper = range

        max_value = cls.max_value()

        scaled = (value-lower) * (float(max_value)/(upper-lower))

        return scaled

    @classmethod

    def clip_value(cls, value):

        clipped = max(0, min(value, cls.max_value()))

        return clipped

    @classmethod

    def int_scale_value(cls, value, range):

        scaled = int(round(cls.float_scale_value(value, range)))

        return scaled

    @classmethod

    def scale_value(cls, value, range):

        scaled = cls.int_scale_value(value, range)

        clipped = cls.clip_value(scaled)

        return clipped

class SimpleData(Data):

    enc_map = 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789'

    def __repr__(self):

        max_value = self.max_value()

        encoded_data = []

        for data in self.data:

            sub_data = []

            for value in data:

                if value is None:

                    sub_data.append('_')

                elif value >= 0 and value <= max_value:

                    sub_data.append(SimpleData.enc_map[value])

                else:

                    raise DataOutOfRangeException('cannot encode value: %d'

                                                  % value)

            encoded_data.append(''.join(sub_data))

        return 'chd=s:' + ','.join(encoded_data)

    @staticmethod

    def max_value():

        return 61

class TextData(Data):

    def __repr__(self):

        max_value = self.max_value()

        encoded_data = []

        for data in self.data:

            sub_data = []

            for value in data:

                if value is None:

                    sub_data.append(-1)

                elif value >= 0 and value <= max_value:

                    sub_data.append("%.1f" % float(value))

                else:

                    raise DataOutOfRangeException()

            encoded_data.append(','.join(sub_data))

        return 'chd=t:' + '|'.join(encoded_data)

    @staticmethod

    def max_value():

        return 100

    @classmethod

    def scale_value(cls, value, range):

        lower, upper = range

        if upper > lower:

            max_value = cls.max_value()

            scaled = (float(value) - lower) * max_value / upper

            clipped = max(0, min(scaled, max_value))

            return clipped

        else:

            return lower

    @classmethod

    def scale_value(cls, value, range):

        # use float values instead of integers because we don't need an encode

        # map index

        scaled = cls.float_scale_value(value,range)

        clipped = cls.clip_value(scaled)

        return clipped

class ExtendedData(Data):

    enc_map = \

        'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789-.'

    def __repr__(self):

        max_value = self.max_value()

        encoded_data = []

        enc_size = len(ExtendedData.enc_map)

        for data in self.data:

            sub_data = []

            for value in data:

                if value is None:

                    sub_data.append('__')

                elif value >= 0 and value <= max_value:

                    first, second = divmod(int(value), enc_size)

                    sub_data.append('%s%s' % (

                        ExtendedData.enc_map[first],

                        ExtendedData.enc_map[second]))

                else:

                    raise DataOutOfRangeException( \

                        'Item #%i "%s" is out of range' % (data.index(value), \

                        value))

            encoded_data.append(''.join(sub_data))

        return 'chd=e:' + ','.join(encoded_data)

    @staticmethod

    def max_value():

        return 4095

# Axis Classes

# -----------------------------------------------------------------------------

class Axis(object):

    BOTTOM = 'x'

    TOP = 't'

    LEFT = 'y'

    RIGHT = 'r'

    TYPES = (BOTTOM, TOP, LEFT, RIGHT)

    def __init__(self, axis_index, axis_type, **kw):

        assert(axis_type in Axis.TYPES)

        self.has_style = False

        self.axis_index = axis_index

        self.axis_type = axis_type

        self.positions = None

    def set_index(self, axis_index):

        self.axis_index = axis_index

    def set_positions(self, positions):

        self.positions = positions

    def set_style(self, colour, font_size=None, alignment=None):

        _check_colour(colour)

        self.colour = colour

        self.font_size = font_size

        self.alignment = alignment

        self.has_style = True

    def style_to_url(self):

        bits = []

        bits.append(str(self.axis_index))

        bits.append(self.colour)

        if self.font_size is not None:

            bits.append(str(self.font_size))

            if self.alignment is not None:

                bits.append(str(self.alignment))

        return ','.join(bits)

    def positions_to_url(self):

        bits = []

        bits.append(str(self.axis_index))

        bits += [str(a) for a in self.positions]

        return ','.join(bits)

class LabelAxis(Axis):

    def __init__(self, axis_index, axis_type, values, **kwargs):

        Axis.__init__(self, axis_index, axis_type, **kwargs)

        self.values = [str(a) for a in values]

    def __repr__(self):

        return '%i:|%s' % (self.axis_index, '|'.join(self.values))

class RangeAxis(Axis):

    def __init__(self, axis_index, axis_type, low, high, **kwargs):

        Axis.__init__(self, axis_index, axis_type, **kwargs)

        self.low = low

        self.high = high

    def __repr__(self):

        return '%i,%s,%s' % (self.axis_index, self.low, self.high)

# Chart Classes

# -----------------------------------------------------------------------------

class Chart(object):

    """Abstract class for all chart types.

    width are height specify the dimensions of the image. title sets the title

    of the chart. legend requires a list that corresponds to datasets.

    """

    BASE_URL = 'http://chart.apis.google.com/chart?'

    BACKGROUND = 'bg'

    CHART = 'c'

    SOLID = 's'

    LINEAR_GRADIENT = 'lg'

    LINEAR_STRIPES = 'ls'

    def __init__(self, width, height, title=None, legend=None, colours=None,

                 auto_scale=True, x_range=None, y_range=None):

        assert(type(self) != Chart)  # This is an abstract class

        assert(isinstance(width, int))

        assert(isinstance(height, int))

        self.width = width

        self.height = height

        self.data = []

        self.set_title(title)

        self.set_legend(legend)

        self.set_colours(colours)

        # Data for scaling.

        self.auto_scale = auto_scale    # Whether to automatically scale data

        self.x_range = x_range          # (min, max) x-axis range for scaling

        self.y_range = y_range          # (min, max) y-axis range for scaling

        self.scaled_data_class = None

        self.scaled_x_range = None

        self.scaled_y_range = None

        self.fill_types = {

            Chart.BACKGROUND: None,

            Chart.CHART: None,

        }

        self.fill_area = {

            Chart.BACKGROUND: None,

            Chart.CHART: None,

        }

        self.axis = []

        self.markers = []

    # URL generation

    # -------------------------------------------------------------------------

    def get_url(self, data_class=None):

        url_bits = self.get_url_bits(data_class=data_class)

        return self.BASE_URL + '&'.join(url_bits)

    def get_url_bits(self, data_class=None):

        url_bits = []

        # required arguments

        url_bits.append(self.type_to_url())

        url_bits.append('chs=%ix%i' % (self.width, self.height))

        url_bits.append(self.data_to_url(data_class=data_class))

        # optional arguments

        if self.title:

            url_bits.append('chtt=%s' % self.title)

        if self.legend:

            url_bits.append('chdl=%s' % '|'.join(self.legend))

        if self.colours:

            url_bits.append('chco=%s' % ','.join(self.colours))

        ret = self.fill_to_url()

        if ret:

            url_bits.append(ret)

        ret = self.axis_to_url()

        if ret:

            url_bits.append(ret)

        if self.markers:

            url_bits.append(self.markers_to_url())

        return url_bits

    # Downloading

    # -------------------------------------------------------------------------

    def download(self, file_name):

        opener = urllib2.urlopen(self.get_url())

        if opener.headers['content-type'] != 'image/png':

            raise BadContentTypeException('Server responded with a ' \

                'content-type of %s' % opener.headers['content-type'])

        open(file_name, 'wb').write(urllib.urlopen(self.get_url()).read())

    # Simple settings

    # -------------------------------------------------------------------------

    def set_title(self, title):

        if title:

            self.title = urllib.quote(title)

        else:

            self.title = None

    def set_legend(self, legend):

        """legend needs to be a list, tuple or None"""

        assert(isinstance(legend, list) or isinstance(legend, tuple) or

            legend is None)

        if legend:

            self.legend = [urllib.quote(a) for a in legend]

        else:

            self.legend = None

    # Chart colours

    # -------------------------------------------------------------------------

    def set_colours(self, colours):

        # colours needs to be a list, tuple or None

        assert(isinstance(colours, list) or isinstance(colours, tuple) or

            colours is None)

        # make sure the colours are in the right format

        if colours:

            for col in colours:

                _check_colour(col)

        self.colours = colours

    # Background/Chart colours

    # -------------------------------------------------------------------------

    def fill_solid(self, area, colour):

        assert(area in (Chart.BACKGROUND, Chart.CHART))

        _check_colour(colour)

        self.fill_area[area] = colour

        self.fill_types[area] = Chart.SOLID

    def _check_fill_linear(self, angle, *args):

        assert(isinstance(args, list) or isinstance(args, tuple))

        assert(angle >= 0 and angle <= 90)

        assert(len(args) % 2 == 0)

        args = list(args)  # args is probably a tuple and we need to mutate

        for a in xrange(len(args) / 2):

            col = args[a * 2]

            offset = args[a * 2 + 1]

            _check_colour(col)

            assert(offset >= 0 and offset <= 1)

            args[a * 2 + 1] = str(args[a * 2 + 1])

        return args

    def fill_linear_gradient(self, area, angle, *args):

        assert(area in (Chart.BACKGROUND, Chart.CHART))

        args = self._check_fill_linear(angle, *args)

        self.fill_types[area] = Chart.LINEAR_GRADIENT

        self.fill_area[area] = ','.join([str(angle)] + args)

    def fill_linear_stripes(self, area, angle, *args):

        assert(area in (Chart.BACKGROUND, Chart.CHART))

        args = self._check_fill_linear(angle, *args)

        self.fill_types[area] = Chart.LINEAR_STRIPES

        self.fill_area[area] = ','.join([str(angle)] + args)

    def fill_to_url(self):

        areas = []

        for area in (Chart.BACKGROUND, Chart.CHART):

            if self.fill_types[area]:

                areas.append('%s,%s,%s' % (area, self.fill_types[area], \

                    self.fill_area[area]))

        if areas:

            return 'chf=' + '|'.join(areas)

    # Data

    # -------------------------------------------------------------------------

    def data_class_detection(self, data):

        """Determines the appropriate data encoding type to give satisfactory

        resolution (http://code.google.com/apis/chart/#chart_data).

        """

        assert(isinstance(data, list) or isinstance(data, tuple))

        if not isinstance(self, (LineChart, BarChart, ScatterChart)):

            # From the link above:

            #   Simple encoding is suitable for all other types of chart

            #   regardless of size.

            return SimpleData

        elif self.height < 100:

            # The link above indicates that line and bar charts less

            # than 300px in size can be suitably represented with the

            # simple encoding. I've found that this isn't sufficient,

            # e.g. examples/line-xy-circle.png. Let's try 100px.

            return SimpleData

        else:

            return ExtendedData

    def data_x_range(self):

        """Return a 2-tuple giving the minimum and maximum x-axis

        data range.

        """

        try:

            lower = min([min(s) for type, s in self.annotated_data()

                         if type == 'x'])

            upper = max([max(s) for type, s in self.annotated_data()

                         if type == 'x'])

            return (lower, upper)

        except ValueError:

            return None     # no x-axis datasets

    def data_y_range(self):

        """Return a 2-tuple giving the minimum and maximum y-axis

        data range.

        """

        try:

            lower = min([min(s) for type, s in self.annotated_data()

                         if type == 'y'])

            upper = max([max(s) for type, s in self.annotated_data()

                         if type == 'y'])

            return (lower, upper)

        except ValueError:

            return None     # no y-axis datasets

    def scaled_data(self, data_class, x_range=None, y_range=None):

        """Scale `self.data` as appropriate for the given data encoding

        (data_class) and return it.

        An optional `y_range` -- a 2-tuple (lower, upper) -- can be

        given to specify the y-axis bounds. If not given, the range is

        inferred from the data: (0, <max-value>) presuming no negative

        values, or (<min-value>, <max-value>) if there are negative

        values.  `self.scaled_y_range` is set to the actual lower and

        upper scaling range.

        Ditto for `x_range`. Note that some chart types don't have x-axis

        data.

        """

        self.scaled_data_class = data_class

        # Determine the x-axis range for scaling.

        if x_range is None:

            x_range = self.data_x_range()

            if x_range and x_range[0] > 0:

                x_range = (0, x_range[1])

        self.scaled_x_range = x_range

        # Determine the y-axis range for scaling.

        if y_range is None:

            y_range = self.data_y_range()

            if y_range and y_range[0] > 0:

                y_range = (0, y_range[1])

        self.scaled_y_range = y_range

        scaled_data = []

        for type, dataset in self.annotated_data():

            if type == 'x':

                scale_range = x_range

            elif type == 'y':

                scale_range = y_range

            elif type == 'marker-size':

                scale_range = (0, max(dataset))

            scaled_data.append([data_class.scale_value(v, scale_range)

                                for v in dataset])

        return scaled_data

    def add_data(self, data):

        self.data.append(data)

        return len(self.data) - 1  # return the "index" of the data set

    def data_to_url(self, data_class=None):

        if not data_class:

            data_class = self.data_class_detection(self.data)

        if not issubclass(data_class, Data):

            raise UnknownDataTypeException()

        if self.auto_scale:

            data = self.scaled_data(data_class, self.x_range, self.y_range)

        else:

            data = self.data

        return repr(data_class(data))

    # Axis Labels

    # -------------------------------------------------------------------------

    def set_axis_labels(self, axis_type, values):

        assert(axis_type in Axis.TYPES)

        values = [ urllib.quote(a) for a in values ]

        axis_index = len(self.axis)

        axis = LabelAxis(axis_index, axis_type, values)

        self.axis.append(axis)

        return axis_index

    def set_axis_range(self, axis_type, low, high):

        assert(axis_type in Axis.TYPES)

        axis_index = len(self.axis)

        axis = RangeAxis(axis_index, axis_type, low, high)

        self.axis.append(axis)

        return axis_index

    def set_axis_positions(self, axis_index, positions):

        try:

            self.axis[axis_index].set_positions(positions)

        except IndexError:

            raise InvalidParametersException('Axis index %i has not been ' \

                'created' % axis)

    def set_axis_style(self, axis_index, colour, font_size=None, \

            alignment=None):

        try:

            self.axis[axis_index].set_style(colour, font_size, alignment)

        except IndexError:

            raise InvalidParametersException('Axis index %i has not been ' \

                'created' % axis)

    def axis_to_url(self):

        available_axis = []

        label_axis = []

        range_axis = []

        positions = []

        styles = []

        index = -1

        for axis in self.axis:

            available_axis.append(axis.axis_type)

            if isinstance(axis, RangeAxis):

                range_axis.append(repr(axis))

            if isinstance(axis, LabelAxis):

                label_axis.append(repr(axis))

            if axis.positions:

                positions.append(axis.positions_to_url())

            if axis.has_style:

                styles.append(axis.style_to_url())

        if not available_axis:

            return

        url_bits = []

        url_bits.append('chxt=%s' % ','.join(available_axis))

        if label_axis:

            url_bits.append('chxl=%s' % '|'.join(label_axis))

        if range_axis:

            url_bits.append('chxr=%s' % '|'.join(range_axis))

        if positions:

            url_bits.append('chxp=%s' % '|'.join(positions))

        if styles:

            url_bits.append('chxs=%s' % '|'.join(styles))

        return '&'.join(url_bits)

    # Markers, Ranges and Fill area (chm)

    # -------------------------------------------------------------------------

    def markers_to_url(self):

        return 'chm=%s' % '|'.join([','.join(a) for a in self.markers])

    def add_marker(self, index, point, marker_type, colour, size):

        self.markers.append((marker_type, colour, str(index), str(point), \

            str(size)))

    def add_horizontal_range(self, colour, start, stop):

        self.markers.append(('r', colour, '1', str(start), str(stop)))

    def add_vertical_range(self, colour, start, stop):

        self.markers.append(('R', colour, '1', str(start), str(stop)))

    def add_fill_range(self, colour, index_start, index_end):

        self.markers.append(('b', colour, str(index_start), str(index_end), \

            '1'))

    def add_fill_simple(self, colour):

        self.markers.append(('B', colour, '1', '1', '1'))

class ScatterChart(Chart):

    def type_to_url(self):

        return 'cht=s'

    def annotated_data(self):

        yield ('x', self.data[0])

        yield ('y', self.data[1])

        if len(self.data) > 2:

            # The optional third dataset is relative sizing for point

            # markers.

            yield ('marker-size', self.data[2])

class LineChart(Chart):

    def __init__(self, *args, **kwargs):

        assert(type(self) != LineChart)  # This is an abstract class

        Chart.__init__(self, *args, **kwargs)

        self.line_styles = {}

        self.grid = None

    def set_line_style(self, index, thickness=1, line_segment=None, \

            blank_segment=None):

        value = []

        value.append(str(thickness))

        if line_segment:

            value.append(str(line_segment))

            value.append(str(blank_segment))

        self.line_styles[index] = value

    def set_grid(self, x_step, y_step, line_segment=1, \

            blank_segment=0):

        self.grid = '%s,%s,%s,%s' % (x_step, y_step, line_segment, \

            blank_segment)

    def get_url_bits(self, data_class=None):

        url_bits = Chart.get_url_bits(self, data_class=data_class)

        if self.line_styles:

            style = []

            # for index, values in self.line_style.items():

            for index in xrange(max(self.line_styles) + 1):

                if index in self.line_styles:

                    values = self.line_styles[index]

                else:

                    values = ('1', )

                style.append(','.join(values))

            url_bits.append('chls=%s' % '|'.join(style))

        if self.grid:

            url_bits.append('chg=%s' % self.grid)

        return url_bits

class SimpleLineChart(LineChart):

    def type_to_url(self):

        return 'cht=lc'

    def annotated_data(self):

        # All datasets are y-axis data.

        for dataset in self.data:

            yield ('y', dataset)

class SparkLineChart(SimpleLineChart):

    def type_to_url(self):

        return 'cht=ls'

class XYLineChart(LineChart):

    def type_to_url(self):

        return 'cht=lxy'

    def annotated_data(self):

        # Datasets alternate between x-axis, y-axis.

        for i, dataset in enumerate(self.data):

            if i % 2 == 0:

                yield ('x', dataset)

            else:

                yield ('y', dataset)

class BarChart(Chart):

    def __init__(self, *args, **kwargs):

        assert(type(self) != BarChart)  # This is an abstract class

        Chart.__init__(self, *args, **kwargs)

        self.bar_width = None

    def set_bar_width(self, bar_width):

        self.bar_width = bar_width

    def get_url_bits(self, data_class=None):

        url_bits = Chart.get_url_bits(self, data_class=data_class)

        if self.bar_width is not None:

            url_bits.append('chbh=%i' % self.bar_width)

        return url_bits

class StackedHorizontalBarChart(BarChart):