pygal/lib/SVG/__init__.py

#!python
# -*- coding: UTF-8 -*-

__all__ = ('Plot', 'TimeSeries', 'Bar', 'Pie', 'Schedule')

from xml.dom import minidom as dom
from operator import itemgetter
from itertools import islice
from cssutils import css, stylesheets

try:
	import zlib
	__have_zlib = True
except ImportError:
	__have_zlib = False

def sort_multiple(arrays):
	"sort multiple lists (of equal size) using the first list for the sort keys"
	tuples = zip(*arrays)
	tuples.sort()
	return zip(*tuples)
	
class Graph(object):
	"""=== Base object for generating SVG Graphs

== Synopsis

This class is only used as a superclass of specialized charts.  Do not
attempt to use this class directly, unless creating a new chart type.

For examples of how to subclass this class, see the existing specific
subclasses, such as SVG.Pie.

== Examples

For examples of how to use this package, see either the test files, or
the documentation for the specific class you want to use.

* file:test/plot.rb
* file:test/single.rb
* file:test/test.rb
* file:test/timeseries.rb

== Description

This package should be used as a base for creating SVG graphs.

== Acknowledgements

Sean E. Russel for creating the SVG::Graph Ruby package from which this
Python port is derived.

Leo Lapworth for creating the SVG::TT::Graph package which the Ruby
port is based on.

Stephen Morgan for creating the TT template and SVG.

== See

* SVG.BarHorizontal
* SVG.Bar
* SVG.Line
* SVG.Pie
* SVG.Plot
* SVG.TimeSeries

== Author

Jason R. Coombs <jaraco@jaraco.com>

Copyright © 2008 Jason R. Coombs
"""
	width=                500
	height=               300
	show_x_guidelines=    False
	show_y_guidelines=    True
	show_data_values=     True
	min_scale_value=      None
	show_x_labels=        True
	stagger_x_labels=     False
	rotate_x_labels=      False
	step_x_labels=        1
	step_include_first_x_label= True
	show_y_labels=        True
	rotate_y_labels=      False
	stagger_y_labels=     False
	step_include_first_y_label= True
	step_y_labels=        1
	scale_integers=       False
	show_x_title=         False
	x_title=              'X Field names'
	show_y_title=         False
	y_title_text_direction= 'bt' # 'bt' for bottom to top; 'tb' for top to bottom
	y_title=              'Y Scale'
	show_graph_title=     False
	graph_title=          'Graph Title'
	show_graph_subtitle=  False
	graph_subtitle=       'Graph Subtitle'
	key=                  True
	key_position=         'right' # 'bottom' or 'right',
	
	font_size=            12
	title_font_size=      16
	subtitle_font_size=   14
	x_label_font_size=    12
	x_title_font_size=    14
	y_label_font_size=    12
	y_title_font_size=    14
	key_font_size=        10
	
	no_css=               False
	add_popups=           False

	top_align = top_font = right_align = right_font = 0

	def __init__(self, config = {}):
		"""Initialize the graph object with the graph settings."""
		if self.__class__ is Graph:
			raise NotImplementedError, "Graph is an abstract base class"
		self.load_config(config)
		self.clear_data()

	def load_config(self, config):
		self.__dict__.update(config)
		
	def add_data(self, conf):
		"""This method allows you do add data to the graph object.
		It can be called several times to add more data sets in.
		
		>>> data_sales_02 = [12, 45, 21] # doctest: +SKIP
		>>> graph.add_data({ # doctest: +SKIP
		...  'data': data_sales_02,
		...  'title': 'Sales 2002'
		... }) # doctest: +SKIP
		"""
		self.validate_data(conf)
		self.process_data(conf)
		self.data.append(conf)

	def validate_data(self, conf):
		try:
			assert(isinstance(conf['data'], (tuple, list)))
		except TypeError, e:
			raise TypeError, "conf should be dictionary with 'data' and other items"
		except AssertionError:
			if not hasattr(conf['data'], '__iter__'):
				raise TypeError, "conf['data'] should be tuple or list or iterable"

	def process_data(self, data): pass
	
	def clear_data(self):
		"""This method removes all data from the object so that you can
		reuse it to create a new graph but with the same config options.
		
		>>> graph.clear_data() # doctest: +SKIP
		"""
		self.data = []
		
	def burn(self):
		"""This method processes the template with the data and
		config which has been set and returns the resulting SVG.
		
		This method will croak unless at least one data set has
		been added to the graph object.
		
		Ex: graph.burn()"""
		if not self.data: raise ValueError("No data available")
		
		if hasattr(self, 'calculations'): self.calculations()
		
		self.start_svg()
		self.calculate_graph_dimensions()
		self.foreground = self._create_element("g")
		self.draw_graph()
		self.draw_titles()
		self.draw_legend()
		self.draw_data()
		self.graph.appendChild(self.foreground)
		self.style()
		
		data = self._doc.toprettyxml()
		
		if hasattr(self, 'compress') and self.compress:
			if __have_zlib:
				data = zlib.compress(data)
			else:
				data += '<!-- Python zlib not available for SVGZ -->'
				
		return data
	
	KEY_BOX_SIZE = 12
	
	def calculate_left_margin(self):
		"""Override this (and call super) to change the margin to the left
		of the plot area.  Results in border_left being set."""
		bl = 7
		# Check for Y labels
		if self.rotate_y_labels:
			max_y_label_height_px = self.y_label_font_size
		else:
			label_lengths = map(len, self.get_y_labels())
			max_y_label_len = max(label_lengths)
			max_y_label_height_px = 0.6 * max_y_label_len * self.y_label_font_size
		if self.show_y_labels: bl += max_y_label_height_px
		if self.stagger_y_labels: bl += max_y_label_height_px + 10
		if self.show_y_title: bl += self.y_title_font_size + 5
		self.border_left = bl
		
	def max_y_label_width_px(self):
		"""Calculates the width of the widest Y label.  This will be the
		character height if the Y labels are rotated."""
		if self.rotate_y_labels:
			return self.font_size
		
	def calculate_right_margin(self):
		"""Override this (and call super) to change the margin to the right
		of the plot area.  Results in border_right being set."""
		br = 7
		if self.key and self.key_position == 'right':
			max_key_len = max(map(len, self.keys()))
			br += max_key_len * self.key_font_size * 0.6
			br += self.KEY_BOX_SIZE
			br += 10		# Some padding around the box
		self.border_right = br
		
	def calculate_top_margin(self):
		"""Override this (and call super) to change the margin to the top
		of the plot area.  Results in border_top being set."""
		self.border_top = 5
		if self.show_graph_title: self.border_top += self.title_font_size
		self.border_top += 5
		if self.show_graph_subtitle: self.border_top += self.subtitle_font_size
		
	def add_popup(self, x, y, label):
		"Adds pop-up point information to a graph."
		txt_width = len(label) * self.font_size * 0.6 + 10
		tx = x + [5,-5][int(x+txt_width > self.width)]
		t = self._create_element('text')
		anchor = ['start', 'end'][x+txt_width > self.width]
		style = 'fill: #000; text-anchor: %s;' % anchor
		id = 'label-%s' % label
		attributes = {'x': str(tx),
					  'y': str(y - self.font_size),
					  'visibility': 'hidden',
					  'style': style,
					  'text': label,
					  'id': id
					  }
		map(lambda a: t.setAttribute(*a), attributes.items())
		self.foreground.appendChild(t)
		
		visibility = "document.getElementById(%s).setAttribute('visibility', %%s)" % id
		t = self._create_element('circle')
		attributes = {'cx': str(x),
					  'cy': str(y),
					  'r': 10,
					  'style': 'opacity: 0;',
					  'onmouseover': visibility % 'visible',
					  'onmouseout': visibility % 'hidden',
		}
		map(lambda a: t.setAttribute(*a), attributes.items())

	def calculate_bottom_margin(self):
		"""Override this (and call super) to change the margin to the bottom
		of the plot area.  Results in border_bottom being set."""
		bb = 7
		if self.key and self.key_position == 'bottom':
			bb += len(self.data) * (self.font_size + 5)
			bb += 10
		if self.show_x_labels:
			max_x_label_height_px = self.x_label_font_size
			if self.rotate_x_labels:
				label_lengths = map(len, self.get_x_labels())
				max_x_label_len = reduce(max, label_lengths)
				max_x_label_height_px *= 0.6 * max_x_label_len
			bb += max_x_label_height_px
			if self.stagger_x_labels: bb += max_x_label_height_px + 10
		if self.show_x_title: bb += self.x_title_font_size + 5
		self.border_bottom = bb
		
	def draw_graph(self):
		transform = 'translate (%s %s)' % (self.border_left, self.border_top)
		self.graph = self._create_element('g', {'transform': transform})
		self.root.appendChild(self.graph)
		
		self.graph.appendChild(self._create_element('rect', {
			'x': '0',
			'y': '0',
			'width': str(self.graph_width),
			'height': str(self.graph_height),
			'class': 'graphBackground'
			}))
		
		#Axis
		self.graph.appendChild(self._create_element('path', {
			'd': 'M 0 0 v%s' % self.graph_height,
			'class': 'axis',
			'id': 'xAxis'
		}))
		self.graph.appendChild(self._create_element('path', {
			'd': 'M 0 %s h%s' % (self.graph_height, self.graph_width),
			'class': 'axis',
			'id': 'yAxis'
		}))
		
		self.draw_x_labels()
		self.draw_y_labels()
	
	def x_label_offset(self, width):
		"""Where in the X area the label is drawn
		Centered in the field, should be width/2.  Start, 0."""
		return 0

	def make_datapoint_text(self, x, y, value, style=''):
		if self.show_data_values:
			e = self._create_element('text', {
				'x': str(x),
				'y': str(y),
				'class': 'dataPointLabel',
				'style': '%(style)s stroke: #fff; stroke-width: 2;' % vars(),
			})
			e.appendChild(self._doc.createTextNode(str(value)))
			self.foreground.appendChild(e)
			e = self._create_element('text', {
				'x': str(x),
				'y': str(y),
				'class': 'dataPointLabel'})
			e.appendChild(self._doc.createTextNode(str(value)))
			if style: e.setAttribute('style', style)
			self.foreground.appendChild(e)

	def draw_x_labels(self):
		"Draw the X axis labels"
		if self.show_x_labels:
			labels = self.get_x_labels()
			count = len(labels)
			
			labels = enumerate(iter(labels))
			start = int(not self.step_include_first_x_label)
			labels = islice(labels, start, None, self.step_x_labels)
			map(self.draw_x_label, labels)
			self.draw_x_guidelines(self.field_width(), count)
	
	def draw_x_label(self, label):
		label_width = self.field_width()
		index, label = label
		text = self._create_element('text', {'class': 'xAxisLabels'})
		text.appendChild(self._doc.createTextNode(label))
		self.graph.appendChild(text)
		
		x = index * label_width + self.x_label_offset(label_width)
		y = self.graph_height + self.x_label_font_size + 3
		t = 0 - (self.font_size / 2)
		
		if self.stagger_x_labels and  (index % 2):
			stagger = self.x_label_font_size + 5
			y += stagger
			graph_height = self.graph_height
			path = self._create_element('path', {
				'd': 'M%(x)f %(graph_height)f v%(stagger)d' % vars(),
				'class': 'staggerGuideLine'
			})
			self.graph.appendChild(path)
			
		text.setAttribute('x', str(x))
		text.setAttribute('y', str(y))
		
		if self.rotate_x_labels:
			transform = 'rotate(90 %d %d) translate(0 -%d)' % \
				(x, y-self.x_label_font_size, self.x_label_font_size/4)
			text.setAttribute('transform', transform)
			text.setAttribute('style', 'text-anchor: start')
		else:
			text.setAttribute('style', 'text-anchor: middle')
			
	def y_label_offset(self, height):
		"""Where in the Y area the label is drawn
		Centered in the field, should be width/2.  Start, 0."""
		return 0
	
	def get_field_width(self):
		return float(self.graph_width - self.font_size*2*self.right_font) / \
			(len(self.get_x_labels()) - self.right_align)
	field_width = get_field_width
	
	def get_field_height(self):
		return float(self.graph_height - self.font_size*2*self.top_font) / \
			(len(self.get_y_labels()) - self.top_align)
	field_height = get_field_height

	def draw_y_labels(self):
		"Draw the Y axis labels"
		if self.show_y_labels:
			labels = self.get_y_labels()
			count = len(labels)
			
			labels = enumerate(iter(labels))
			start = int(not self.step_include_first_y_label)
			labels = islice(labels, start, None, self.step_y_labels)
			map(self.draw_y_label, labels)
			self.draw_y_guidelines(self.field_height(), count)

	def get_y_offset(self):
		#result = self.graph_height + self.y_label_offset(label_height)
		result = self.graph_height + self.y_label_offset(self.field_height())
		if not self.rotate_y_labels: result += self.font_size/1.2
		return result
	y_offset = property(get_y_offset)
	
	def draw_y_label(self, label):
		label_height = self.field_height()
		index, label = label
		text = self._create_element('text', {'class': 'yAxisLabels'})
		text.appendChild(self._doc.createTextNode(label))
		self.graph.appendChild(text)
		
		y = self.y_offset - (label_height * index)
		x = {True: 0, False:-3}[self.rotate_y_labels]
		
		if self.stagger_y_labels and  (index % 2):
			stagger = self.y_label_font_size + 5
			x -= stagger
			path = self._create_element('path', {
				'd': 'M%(x)f %(y)f h%(stagger)d' % vars(),
				'class': 'staggerGuideLine'
			})
			self.graph.appendChild(path)
			
		text.setAttribute('x', str(x))
		text.setAttribute('y', str(y))
		
		if self.rotate_y_labels:
			transform = 'translate(-%d 0) rotate (90 %d %d)' % \
				(self.font_size, x, y)
			text.setAttribute('transform', transform)
			text.setAttribute('style', 'text-anchor: middle')
		else:
			text.setAttribute('y', str(y - self.y_label_font_size/2))
			text.setAttribute('style', 'text-anchor: end')
		
	def draw_x_guidelines(self, label_height, count):
		"Draw the X-axis guidelines"
		if not self.show_x_guidelines: return
		# skip the first one
		for count in range(1,count):
			start = label_height*count
			stop = self.graph_height
			path = self._create_element('path', {
				'd': 'M %(start)s 0 v%(stop)s' % vars(),
				'class': 'guideLines'})
			self.graph.appendChild(path)
			

	def draw_y_guidelines(self, label_height, count):
		"Draw the Y-axis guidelines"
		if not self.show_y_guidelines: return
		for count in range(1, count):
			start = self.graph_height - label_height*count
			stop = self.graph_width
			path = self._create_element('path', {
				'd': 'M 0 %(start)s h%(stop)s' % vars(),
				'class': 'guideLines'})
			self.graph.appendChild(path)

	def draw_titles(self):
		"Draws the graph title and subtitle"
		if self.show_graph_title: self.draw_graph_title()
		if self.show_graph_subtitle: self.draw_graph_subtitle()
		if self.show_x_title: self.draw_x_title()
		if self.show_y_title: self.draw_y_title()

	def draw_graph_title(self):
		text = self._create_element('text', {
			'x': str(self.width / 2),
			'y': str(self.title_font_size),
			'class': 'mainTitle'})
		text.appendChild(self._doc.createTextNode(self.graph_title))
		self.root.appendChild(text)

	def draw_graph_subtitle(self):
		y_subtitle_options = [subtitle_font_size, title_font_size+10]
		y_subtitle = y_subtitle_options[self.show_graph_title]
		text = self._create_element('text', {
			'x': str(self.width/2),
			'y': str(y_subtitle),
			'class': 'subTitle',
			})
		text.appendChild(self._doc.createTextNode(self.graph_title))
		self.root.appendChild(text)

	def draw_x_title(self):
		y = self.graph_height + self.border_top + self.x_title_font_size
		if self.show_x_labels:
			y_size = self.x_label_font_size+5
			if self.stagger_x_labels: y_size*=2
			y += y_size
		x = self.width / 2
		
		text = self._create_element('text', {
			'x': str(x),
			'y': str(y),
			'class': 'xAxisTitle',
			})
		text.appendChild(self._doc.createTextNode(self.x_title))
		self.root.appendChild(text)

	def draw_y_title(self):
		x = self.y_title_font_size
		if self.y_title_text_direction=='bt':
				x += 3
				rotate = -90
		else:
				x -= 3
				rotate = 90
		y = self.height / 2
		text = self._create_element('text', {
				'x': str(x),
				'y': str(y),
				'class': 'yAxisTitle',
				})
		text.appendChild(self._doc.createTextNode(self.y_title))
		text.setAttribute('transform', 'rotate(%(rotate)d, %(x)s, %(y)s)' % vars())
		self.root.appendChild(text)

	def keys(self):
		return map(itemgetter('title'), self.data)
	
	def draw_legend(self):
		if self.key:
			group = self._create_element('g')
			self.root.appendChild(group)
			
			for key_count, key_name in enumerate(self.keys()):
				y_offset = (self.KEY_BOX_SIZE * key_count) + (key_count * 5)
				rect = self._create_element('rect', {
					'x': '0',
					'y': str(y_offset),
					'width': str(self.KEY_BOX_SIZE),
					'height': str(self.KEY_BOX_SIZE),
					'class': 'key%s' % (key_count + 1),
				})
				group.appendChild(rect)
				text = self._create_element('text', {
					'x': str(self.KEY_BOX_SIZE + 5),
					'y': str(y_offset + self.KEY_BOX_SIZE),
					'class': 'keyText'})
				text.appendChild(self._doc.createTextNode(key_name))
				group.appendChild(text)
			
			if self.key_position == 'right':
				x_offset = self.graph_width + self.border_left + 10
				y_offset = self.border_top + 20
			if self.key_position == 'bottom':
				x_offset, y_offset = self.calculate_offsets_bottom()
			group.setAttribute('transform', 'translate(%(x_offset)d %(y_offset)d)' % vars())

	def calculate_offsets_bottom(self):
		x_offset = self.border_left + 20
		y_offset = self.border_top + self.graph_height + 5
		if self.show_x_labels:
			max_x_label_height_px = x_label_font_size
			if self.rotate_x_labels:
				longest_label_length = max(map(len, self.get_x_labels()))
				# note: I think 0.6 is the ratio of width to height of characters
				max_x_label_height_px *= longest_label_length * 0.6
			y_offset += max_x_label_height_px
			if self.stagger_x_labels:
				y_offset += max_x_label_height_px + 5
		if self.show_x_title:
			y_offset += x_title_font_size + 5
		return x_offset, y_offset
			
	def style(self):
		"hard code the styles into the xml if style sheets are not used."
		if self.no_css:
			styles = self.parse_css()
			for node in xpath.Evaluate('//*[@class]', self.root):
				cl = node.getAttribute('class')
				style = styles[cl]
				if node.hasAttribute('style'):
					style += node.getAtrtibute('style')
				node.setAttribute('style', style)

	def parse_css(self):
		"""Take a .css file (classes only please) and parse it into a dictionary
		of class/style pairs."""
		css = self.get_style()
		result = {}
		for match in re.finditer('^(?<names>\.(\w+)(?:\s*,\s*\.\w+)*)\s*\{(?<content>[^}]+)\}'):
			names = match.group_dict()['names']
			# apperantly, we're only interested in class names
			names = filter(None, re.split('\s*,?\s*\.'))
			content = match.group_dict()['content']
			# convert all whitespace to 
			content = re.sub('\s+', ' ', content)
			for name in names:
				result[name] = ';'.join(result[name], content)
		return result
			
	def add_defs(self, defs):
		"Override and place code to add defs here"
		pass
	
	def start_svg(self):
		"Base SVG Document Creation"
		impl = dom.getDOMImplementation()
		self._doc = impl.createDocument(None, 'svg', None)
		self.root = self._doc.documentElement
		if hasattr(self, 'style_sheet'):
			pi = self._doc.createProcessingInstruction('xml-stylesheet',
												  'href="%s" type="text/css"' % self.style_sheet)
		attributes = {
			'width': str(self.width),
			'height': str(self.height),
			'viewBox': '0 0 %s %s' % (self.width, self.height),
			'xmlns': 'http://www.w3.org/2000/svg',
			'xmlns:xlink': 'http://www.w3.org/1999/xlink',
			'xmlns:a3': 'http://ns.adobe.com/AdobeSVGViewerExtensions/3.0/',
			'a3:scriptImplementation': 'Adobe'}
		map(lambda a: self.root.setAttribute(*a), attributes.items())
		self.root.appendChild(self._doc.createComment(' Created with SVG.Graph '))
		self.root.appendChild(self._doc.createComment(' SVG.Graph by Jason R. Coombs '))
		self.root.appendChild(self._doc.createComment(' Based on SVG::Graph by Sean E. Russel '))
		self.root.appendChild(self._doc.createComment(' Based on Perl SVG:TT:Graph by Leo Lapworth & Stephan Morgan '))
		self.root.appendChild(self._doc.createComment(' '+'/'*66))

		defs = self._create_element('defs')
		self.add_defs(defs)
		self.root.appendChild(defs)
		if not hasattr(self, 'style_sheet') and not self.no_css:
			self.root.appendChild(self._doc.createComment(' include default stylesheet if none specified '))
			style = self._create_element('style', {'type': 'text/css'})
			defs.appendChild(style)
			style_data = self._doc.createCDATASection(self.get_style())
			style.appendChild(style_data)
			
		self.root.appendChild(self._doc.createComment('SVG Background'))
		rect = self._create_element('rect', {
			'width': str(self.width),
			'height': str(self.height),
			'x': '0',
			'y': '0',
			'class': 'svgBackground'})
		self.root.appendChild(rect)
		
	def calculate_graph_dimensions(self):
		self.calculate_left_margin()
		self.calculate_right_margin()
		self.calculate_bottom_margin()
		self.calculate_top_margin()
		self.graph_width = self.width - self.border_left - self.border_right
		self.graph_height = self.height - self.border_top - self.border_bottom
		
	def get_style(self):
		sheet = css.CSSStyleSheet()
		master_bg_style = css.CSSStyleDeclaration()
		master_bg_style.setProperty('fill', '#ffffff')
		rule = css.CSSStyleRule(selectorText=u'.svgBackground', style=master_bg_style)
		sheet.insertRule(rule)
		result = sheet.cssText
		result = """/* Copy from here for external style sheet */
.svgBackground{
  fill:#ffffff;
}
.graphBackground{
  fill:#f0f0f0;
}

/* graphs titles */
.mainTitle{
  text-anchor: middle;
  fill: #000000;
  font-size: %(title_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}
.subTitle{
  text-anchor: middle;
  fill: #999999;
  font-size: %(subtitle_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}

.axis{
  stroke: #000000;
  stroke-width: 1px;
}

.guideLines{
  stroke: #666666;
  stroke-width: 1px;
  stroke-dasharray: 5 5;
}

.xAxisLabels{
  text-anchor: middle;
  fill: #000000;
  font-size: %(x_label_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}

.yAxisLabels{
  text-anchor: end;
  fill: #000000;
  font-size: %(y_label_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}

.xAxisTitle{
  text-anchor: middle;
  fill: #ff0000;
  font-size: %(x_title_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}

.yAxisTitle{
  fill: #ff0000;
  text-anchor: middle;
  font-size: %(y_title_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}

.dataPointLabel{
  fill: #000000;
  text-anchor:middle;
  font-size: 10px;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}

.staggerGuideLine{
  fill: none;
  stroke: #000000;
  stroke-width: 0.5px;  
}

%%s

.keyText{
  fill: #000000;
  text-anchor:start;
  font-size: %(key_font_size)dpx;
  font-family: "Arial", sans-serif;
  font-weight: normal;
}
/* End copy for external style sheet */
""" % class_dict(self)
		result = result % self.get_css()
		return result

	def _create_element(self, nodeName, attributes={}):
		"Create an XML node and set the attributes from a dict"
		node = self._doc.createElement(nodeName)
		map(lambda a: node.setAttribute(*a), attributes.items())
		return node

class class_dict(object):
	"Emulates a dictionary, but retrieves class attributes"
	def __init__(self, obj):
		self.__obj__ = obj

	def __getitem__(self, item):
		return getattr(self.__obj__, item)

	def keys(self):
		# dir returns a good guess of what attributes might be available
		return dir(self.__obj__)