thuban/test/test_classgen.py

# Copyright (c) 2002, 2003 by Intevation GmbH
# Authors:
# Bernhard Herzog <[email protected]>
#
# This program is free software under the GPL (>=v2)
# Read the file COPYING coming with Thuban for details.

"""
Test the Menu
"""

__version__ = "$Revision$"

import unittest

import support
support.initthuban()

from Thuban.Model.classgen import \
    generate_singletons, \
    generate_uniform_distribution, \
    generate_quantiles, \
    calculate_quantiles, \
    GreyRamp, CustomRamp, FixedRamp
from Thuban.Model.range import Range
from Thuban.Model.color import Color

from Thuban.Model.classification import ClassGroupRange, ClassGroupProperties

class ClassGenTest(unittest.TestCase):

    def doClassRangeTest(self, clazz, ranges):
        self.assertEquals(clazz.GetNumGroups(), len(ranges))
        for i in range(clazz.GetNumGroups()):
            group = clazz.GetGroup(i)
            r1 = str(Range(ranges[i]))
            r2 = group.GetRange()
            self.assertEquals(r1, r2)

        self.doBoundsTest(clazz)

    def doClassSingleTest(self, clazz, _list):
        self.assertEquals(clazz.GetNumGroups(), len(_list))
        for i in range(clazz.GetNumGroups()):
            group = clazz.GetGroup(i)
            self.assertEquals(group.GetValue(), _list[i])

        self.doBoundsTest(clazz)

    def doBoundsTest(self, clazz, ramp = GreyRamp):

        #
        # check that the properties are right (i.e. the first group
        # is all white, the last is all black). This assumes that
        # the GreyRamp, unless another is provided.
        #
        if clazz.GetNumGroups() >= 1:
            groupF = clazz.GetGroup(0)
            first = ramp.GetProperties(0)
            self.assertEquals(groupF.GetProperties(), first)

        if clazz.GetNumGroups() >= 2:
            groupL = clazz.GetGroup(clazz.GetNumGroups() - 1)
            last = ramp.GetProperties(1)
            self.assertEquals(groupL.GetProperties(), last)
            
    def test_generate_singletons(self):
        """Test generate_singletons"""

        eq = self.assertEquals
        gs = generate_singletons
        ramp = GreyRamp

        _list = [1, 2, 3, 4]
        cl = gs(_list, ramp)
        self.doClassSingleTest(cl, _list)

        _list = range(0, 100)
        cl = gs(_list, ramp)
        self.doClassSingleTest(cl, _list)

        _list = range(-100, 100)
        cl = gs(_list, ramp)
        self.doClassSingleTest(cl, _list)

        _list = ['a', 'b', 'c', 'd']
        cl = gs(_list, ramp)
        self.doClassSingleTest(cl, _list)

        _list = []
        cl = gs(_list, ramp)
        self.doClassSingleTest(cl, _list)

        _list = [1]
        cl = gs(_list, ramp)
        self.doClassSingleTest(cl, _list)
        

    def test_generate_uniform_distribution(self):
        """Test generate_uniform_distribution"""

        eq = self.assertEquals
        gud = generate_uniform_distribution
        ramp = GreyRamp

        cl = gud(0, 99, 10, ramp, True)
        self.doClassRangeTest(cl, ("[0;10[", "[10;20[", "[20;30[", "[30;40[",
                              "[40;50[", "[50;60[", "[60;70[", "[70;80[",
                              "[80;90[", "[90;99]"))

        cl = gud(0, 99, 10, ramp, False)
        self.doClassRangeTest(cl, ("[0;9.9[", "[9.9;19.8[", "[19.8;29.7[", 
                              "[29.7;39.6[", "[39.6;49.5[", "[49.5;59.4[", 
                              "[59.4;69.3[", "[69.3;79.2[", "[79.2;89.1[", 
                              "[89.1;99.0]"))

        cl = gud(1, 2, 2, ramp, False)
        self.doClassRangeTest(cl, ("[1;1.5[", "[1.5;2]"))

        cl = gud(1, 2, 2, ramp, True)
        self.doClassRangeTest(cl, ("[1;2[", "[2;2]"))


    def test_generate_quantiles(self):
        """Test generate_quantiles"""

        eq = self.assertEquals

        #
        # Test calculate_quantiles
        #

        gq = generate_quantiles

        ramp = GreyRamp

        adj, cl = gq([1, 2, 3, 4], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
        self.failIf(adj)
        self.doClassRangeTest(cl, ("[1;1]", "]1;2]", "]2;3]", "]3;4]"))

        adj, cl = gq(range(0, 100), [.25, .5, .75, 1.0], ramp, Range("[0;100["))
        self.failIf(adj)
        self.doClassRangeTest(cl, ("[0;24]", "]24;49]", "]49;74]", "]74;100["))

        adj, cl = gq(range(0, 100), [.33, .66, 1.0], ramp, Range("[0;100]"))
        self.failIf(adj)
        self.doClassRangeTest(cl, ("[0;32]", "]32;65]", "]65;100]"))

        # negative input
        adj,cl = gq(range(-100,100), [.33, .66, 1.0], ramp, Range("[-100;100]"))
        self.failIf(adj)
        self.doClassRangeTest(cl, ("[-100;-35]", "]-35;31]", "]31;100]"))

        # unequal percentiles
        adj,cl = gq(range(0, 100), [.25, .66, .8, 1.0], ramp, Range("[0;100]"))
        self.failIf(adj)
        self.doClassRangeTest(cl, ("[0;24]", "]24;65]", "]65;79]", "]79;100]"))

        # input all the same
        adj,cl = gq([1, 1, 1, 1], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ("[1;4]",))

        # empty input
        adj,cl = gq([], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ())

        # empty range
        adj,cl = gq([1, 2, 3, 4], [.25, .5, .75, 1.0], ramp, Range("]0;1["))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ())

        # empty percentiles
        self.assertRaises(ValueError, gq,
                          [1, 2, 3, 4], [], ramp, Range("]0;1["))

        # single percentile
        self.assertRaises(ValueError, gq,
                          [1, 2, 3, 4], [.5], ramp, Range("[0;4]"))

        # more percentiles than input
        adj,cl = gq([1], [.5, 1.0], ramp, Range("[0;4]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ("[0;4]",))

        adj,cl = gq([1], [.1, .2, .3, .4, .5, .6, .7, .8, .9, 1.0], ramp, Range("[0;4]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ("[0;4]",))

        # range smaller than the input
        adj,cl = gq([1, 2, 3, 4], [.5, 1.0], ramp, Range("[2;3]"))
        self.failIf(adj)
        self.doClassRangeTest(cl, ("[2;2]","]2;3]"))

        # range outside the input
        adj,cl = gq([5, 6, 7, 8], [.5, 1.0], ramp, Range("[2;3]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ())

        adj,cl = gq([1, 1, 1, 1, 1, 1], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ("[1;4]",))

        adj,cl = gq([1, 1, 1, 1, 1, 2, 3], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
        self.failUnless(adj)
        self.doClassRangeTest(cl, ("[1;1]", "]1;2]", "]2;4]"))

        # adjusted quantiles
        adj,cl = gq([1, 1, 1, 1, 1, 
                     2, 2, 2, 2, 2, 
                     3, 3, 3, 3, 3, 
                     4, 4, 4, 4, 4,
                     5, 5, 5, 5, 5], 
                    [.12, .24, .36, .50, .62, .76, .88, 1.0], ramp, Range("[1;5]"))
        
        self.failUnless(adj)
        self.doClassRangeTest(cl, ("[1;1]", "]1;2]", "]2;3]", "]3;4]", "]4;5]"))
        
    def test_calculate_quantiles(self):
        """Test calculate_quantiles"""

        eq = self.assertEquals

        #
        # Test calculate_quantiles
        #

        cq = calculate_quantiles

        result = cq([1, 2, 3, 4], [.25, .5, .75, 1.0], Range("[1;4]"))
        eq(result, (0, 0, 3, [(0, .25), (1, .5), (2, .75), (3, 1.0)]))

        result = cq(range(0, 100), [.25, .5, .75, 1.0], Range("[0;100]"))
        eq(result, (0, 0, 99, [(24, .25), (49, .5), (74, .75), (99, 1.0)]))

        result = cq(range(0, 100), [.33, .66, 1.0], Range("[0;100]"))
        eq(result, (0, 0, 99, [(32, .33), (65, .66), (99, 1.0)]))

        # negative input
        result = cq(range(-100, 100), [.33, .66, 1.0], Range("[-100;100]"))
        eq(result, (0, 0, 199, [(65, .33), (131, .66), (199, 1.0)]))

        # unequal percentiles
        result = cq(range(0, 100), [.25, .66, .8, 1.0], Range("[0;100]"))
        eq(result, (0, 0, 99, [(24, .25), (65, .66), (79, .8), (99, 1.0)]))

        # input all the same
        result = cq([1, 1, 1, 1], [.25, .5, .75, 1.0], Range("[1;4]"))
        eq(result, (1, 0, 3, [(3, 1.0)]))

        # empty input
        result = cq([], [.25, .5, .75, 1.0], Range("[1;4]"))
        eq(result, None)

        # empty range
        result = cq([1, 2, 3, 4], [.25, .5, .75, 1.0], Range("]0;1["))
        eq(result, None)

        # empty percentiles
        self.assertRaises(ValueError, cq, [1, 2, 3, 4], [], Range("]0;1["))

        # single percentile
        self.assertRaises(ValueError, cq, [1, 2, 3, 4], [.5], Range("[0;4]"))

        # percentile doesn't cover range
        self.assertRaises(ValueError, cq, [1, 2, 3, 4], [.5,.8], Range("[0;4]"))

        # more percentiles than input
        result = cq([1], [.5, 1.0], Range("[0;4]"))
        eq(result, (1, 0, 0, [(0, 1.0)]))

        result = cq([1], [.1, .2, .3, .4, .5, .6, .7, .8, .9, 1.0], Range("[0;4]"))
        eq(result, (1, 0, 0, [(0, 1.0)]))

        # range smaller than the input
        result = cq([1, 2, 3, 4], [.5, 1.0], Range("[2;3]"))
        eq(result, (0, 1, 2, [(1, .5), (2, 1.0)]))

        # range outside the input
        result = cq([5, 6, 7, 8], [.5, 1.0], Range("[2;3]"))
        eq(result, None)

        result = cq([1, 1, 1, 1, 1, 1], [.25, .5, .75, 1.0], Range("[1;4]"))
        eq(result, (1, 0, 5, [(5, 1.0)]))

        result = cq([1, 1, 1, 1, 1, 2, 3], [.25, .5, .75, 1.0], Range("[1;4]"))
        eq(result, (1, 0, 6, 
               [(4, 0.7142857142857143), # the algorithm generated
                (5, 0.8571428571428571), # these values, but they are
                (6, 1.0)]))              # right.

        # adjusted quantiles
        result = cq([1, 1, 1, 1, 1, 
                     2, 2, 2, 2, 2, 
                     3, 3, 3, 3, 3, 
                     4, 4, 4, 4, 4,
                     5, 5, 5, 5, 5], 
                    [.12, .24, .36, .50, .62, .76, .88, 1.0], Range("[1;5]"))
        eq(result, (1, 0, 24, [(4, .2), (9, .4), (14, .6), (19, .8), (24, 1.0)]))


class TestCustomRamp(unittest.TestCase):

    def test_color_interpolation(self):
        """Test CustomRamp color interpolation"""
        start = ClassGroupProperties()
        start.SetFill(Color(1, 1, 1))
        start.SetLineColor(Color(0, 0, 0))

        end = ClassGroupProperties()
        end.SetFill(Color(1, 0, 0))
        end.SetLineColor(Color(0, 1, 0))

        ramp = CustomRamp(start, end)
        half = ramp.GetProperties(0.5)
        self.assertEquals(half.GetFill(), Color(1, 0.5, 0.5))
        self.assertEquals(half.GetLineColor(), Color(0, 0.5, 0))

class TestFixedRamp(unittest.TestCase):

    def test(self):
        eq = self.assertEquals

        for lineColor, lineWidth, fillColor in \
            [(None, None, None), (Color(1, 1, 1), None, None),
             (None, 4, None), (None, None, Color(0, 1, 0)),
             (Color(1, 1, 1), 4, None), (Color(1, 1, 1), None, Color(0, 1, 0)),
             (None, 4, Color(0, 1, 0)), (Color(1, 1, 1), 4, Color(0, 1, 0))]:

            framp = FixedRamp(GreyRamp, (lineColor, lineWidth, fillColor))

            for i in [0.0, 0.2, 0.4, 0.6, 0.8, 1.0]:
                props = framp.GetProperties(i)
                if lineColor: eq(props.GetLineColor(), lineColor)
                if lineWidth: eq(props.GetLineWidth(), lineWidth)
                if fillColor: eq(props.GetFill(), fillColor)

if __name__ == "__main__":
    unittest.main()

1	# Copyright (c) 2002, 2003 by Intevation GmbH
2	# Authors:
3	# Bernhard Herzog <[email protected]>
4	#
5	# This program is free software under the GPL (>=v2)
6	# Read the file COPYING coming with Thuban for details.
7
8	"""
9	Test the Menu
10	"""
11
12	__version__ = "$Revision$"
13
14	import unittest
15
16	import support
17	support.initthuban()
18
19	from Thuban.Model.classgen import \
20	generate_singletons, \
21	generate_uniform_distribution, \
22	generate_quantiles, \
23	calculate_quantiles, \
24	GreyRamp, CustomRamp, FixedRamp
25	from Thuban.Model.range import Range
26	from Thuban.Model.color import Color
27
28	from Thuban.Model.classification import ClassGroupRange, ClassGroupProperties
29
30	class ClassGenTest(unittest.TestCase):
31
32	def doClassRangeTest(self, clazz, ranges):
33	self.assertEquals(clazz.GetNumGroups(), len(ranges))
34	for i in range(clazz.GetNumGroups()):
35	group = clazz.GetGroup(i)
36	r1 = str(Range(ranges[i]))
37	r2 = group.GetRange()
38	self.assertEquals(r1, r2)
39
40	self.doBoundsTest(clazz)
41
42	def doClassSingleTest(self, clazz, _list):
43	self.assertEquals(clazz.GetNumGroups(), len(_list))
44	for i in range(clazz.GetNumGroups()):
45	group = clazz.GetGroup(i)
46	self.assertEquals(group.GetValue(), _list[i])
47
48	self.doBoundsTest(clazz)
49
50	def doBoundsTest(self, clazz, ramp = GreyRamp):
51
52	#
53	# check that the properties are right (i.e. the first group
54	# is all white, the last is all black). This assumes that
55	# the GreyRamp, unless another is provided.
56	#
57	if clazz.GetNumGroups() >= 1:
58	groupF = clazz.GetGroup(0)
59	first = ramp.GetProperties(0)
60	self.assertEquals(groupF.GetProperties(), first)
61
62	if clazz.GetNumGroups() >= 2:
63	groupL = clazz.GetGroup(clazz.GetNumGroups() - 1)
64	last = ramp.GetProperties(1)
65	self.assertEquals(groupL.GetProperties(), last)
66
67	def test_generate_singletons(self):
68	"""Test generate_singletons"""
69
70	eq = self.assertEquals
71	gs = generate_singletons
72	ramp = GreyRamp
73
74	_list = [1, 2, 3, 4]
75	cl = gs(_list, ramp)
76	self.doClassSingleTest(cl, _list)
77
78	_list = range(0, 100)
79	cl = gs(_list, ramp)
80	self.doClassSingleTest(cl, _list)
81
82	_list = range(-100, 100)
83	cl = gs(_list, ramp)
84	self.doClassSingleTest(cl, _list)
85
86	_list = ['a', 'b', 'c', 'd']
87	cl = gs(_list, ramp)
88	self.doClassSingleTest(cl, _list)
89
90	_list = []
91	cl = gs(_list, ramp)
92	self.doClassSingleTest(cl, _list)
93
94	_list = [1]
95	cl = gs(_list, ramp)
96	self.doClassSingleTest(cl, _list)
97
98
99	def test_generate_uniform_distribution(self):
100	"""Test generate_uniform_distribution"""
101
102	eq = self.assertEquals
103	gud = generate_uniform_distribution
104	ramp = GreyRamp
105
106	cl = gud(0, 99, 10, ramp, True)
107	self.doClassRangeTest(cl, ("[0;10[", "[10;20[", "[20;30[", "[30;40[",
108	"[40;50[", "[50;60[", "[60;70[", "[70;80[",
109	"[80;90[", "[90;99]"))
110
111	cl = gud(0, 99, 10, ramp, False)
112	self.doClassRangeTest(cl, ("[0;9.9[", "[9.9;19.8[", "[19.8;29.7[",
113	"[29.7;39.6[", "[39.6;49.5[", "[49.5;59.4[",
114	"[59.4;69.3[", "[69.3;79.2[", "[79.2;89.1[",
115	"[89.1;99.0]"))
116
117	cl = gud(1, 2, 2, ramp, False)
118	self.doClassRangeTest(cl, ("[1;1.5[", "[1.5;2]"))
119
120	cl = gud(1, 2, 2, ramp, True)
121	self.doClassRangeTest(cl, ("[1;2[", "[2;2]"))
122
123
124	def test_generate_quantiles(self):
125	"""Test generate_quantiles"""
126
127	eq = self.assertEquals
128
129	#
130	# Test calculate_quantiles
131	#
132
133	gq = generate_quantiles
134
135	ramp = GreyRamp
136
137	adj, cl = gq([1, 2, 3, 4], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
138	self.failIf(adj)
139	self.doClassRangeTest(cl, ("[1;1]", "]1;2]", "]2;3]", "]3;4]"))
140
141	adj, cl = gq(range(0, 100), [.25, .5, .75, 1.0], ramp, Range("[0;100["))
142	self.failIf(adj)
143	self.doClassRangeTest(cl, ("[0;24]", "]24;49]", "]49;74]", "]74;100["))
144
145	adj, cl = gq(range(0, 100), [.33, .66, 1.0], ramp, Range("[0;100]"))
146	self.failIf(adj)
147	self.doClassRangeTest(cl, ("[0;32]", "]32;65]", "]65;100]"))
148
149	# negative input
150	adj,cl = gq(range(-100,100), [.33, .66, 1.0], ramp, Range("[-100;100]"))
151	self.failIf(adj)
152	self.doClassRangeTest(cl, ("[-100;-35]", "]-35;31]", "]31;100]"))
153
154	# unequal percentiles
155	adj,cl = gq(range(0, 100), [.25, .66, .8, 1.0], ramp, Range("[0;100]"))
156	self.failIf(adj)
157	self.doClassRangeTest(cl, ("[0;24]", "]24;65]", "]65;79]", "]79;100]"))
158
159	# input all the same
160	adj,cl = gq([1, 1, 1, 1], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
161	self.failUnless(adj)
162	self.doClassRangeTest(cl, ("[1;4]",))
163
164	# empty input
165	adj,cl = gq([], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
166	self.failUnless(adj)
167	self.doClassRangeTest(cl, ())
168
169	# empty range
170	adj,cl = gq([1, 2, 3, 4], [.25, .5, .75, 1.0], ramp, Range("]0;1["))
171	self.failUnless(adj)
172	self.doClassRangeTest(cl, ())
173
174	# empty percentiles
175	self.assertRaises(ValueError, gq,
176	[1, 2, 3, 4], [], ramp, Range("]0;1["))
177
178	# single percentile
179	self.assertRaises(ValueError, gq,
180	[1, 2, 3, 4], [.5], ramp, Range("[0;4]"))
181
182	# more percentiles than input
183	adj,cl = gq([1], [.5, 1.0], ramp, Range("[0;4]"))
184	self.failUnless(adj)
185	self.doClassRangeTest(cl, ("[0;4]",))
186
187	adj,cl = gq([1], [.1, .2, .3, .4, .5, .6, .7, .8, .9, 1.0], ramp, Range("[0;4]"))
188	self.failUnless(adj)
189	self.doClassRangeTest(cl, ("[0;4]",))
190
191	# range smaller than the input
192	adj,cl = gq([1, 2, 3, 4], [.5, 1.0], ramp, Range("[2;3]"))
193	self.failIf(adj)
194	self.doClassRangeTest(cl, ("[2;2]","]2;3]"))
195
196	# range outside the input
197	adj,cl = gq([5, 6, 7, 8], [.5, 1.0], ramp, Range("[2;3]"))
198	self.failUnless(adj)
199	self.doClassRangeTest(cl, ())
200
201	adj,cl = gq([1, 1, 1, 1, 1, 1], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
202	self.failUnless(adj)
203	self.doClassRangeTest(cl, ("[1;4]",))
204
205	adj,cl = gq([1, 1, 1, 1, 1, 2, 3], [.25, .5, .75, 1.0], ramp, Range("[1;4]"))
206	self.failUnless(adj)
207	self.doClassRangeTest(cl, ("[1;1]", "]1;2]", "]2;4]"))
208
209	# adjusted quantiles
210	adj,cl = gq([1, 1, 1, 1, 1,
211	2, 2, 2, 2, 2,
212	3, 3, 3, 3, 3,
213	4, 4, 4, 4, 4,
214	5, 5, 5, 5, 5],
215	[.12, .24, .36, .50, .62, .76, .88, 1.0], ramp, Range("[1;5]"))
216
217	self.failUnless(adj)
218	self.doClassRangeTest(cl, ("[1;1]", "]1;2]", "]2;3]", "]3;4]", "]4;5]"))
219
220	def test_calculate_quantiles(self):
221	"""Test calculate_quantiles"""
222
223	eq = self.assertEquals
224
225	#
226	# Test calculate_quantiles
227	#
228
229	cq = calculate_quantiles
230
231	result = cq([1, 2, 3, 4], [.25, .5, .75, 1.0], Range("[1;4]"))
232	eq(result, (0, 0, 3, [(0, .25), (1, .5), (2, .75), (3, 1.0)]))
233
234	result = cq(range(0, 100), [.25, .5, .75, 1.0], Range("[0;100]"))
235	eq(result, (0, 0, 99, [(24, .25), (49, .5), (74, .75), (99, 1.0)]))
236
237	result = cq(range(0, 100), [.33, .66, 1.0], Range("[0;100]"))
238	eq(result, (0, 0, 99, [(32, .33), (65, .66), (99, 1.0)]))
239
240	# negative input
241	result = cq(range(-100, 100), [.33, .66, 1.0], Range("[-100;100]"))
242	eq(result, (0, 0, 199, [(65, .33), (131, .66), (199, 1.0)]))
243
244	# unequal percentiles
245	result = cq(range(0, 100), [.25, .66, .8, 1.0], Range("[0;100]"))
246	eq(result, (0, 0, 99, [(24, .25), (65, .66), (79, .8), (99, 1.0)]))
247
248	# input all the same
249	result = cq([1, 1, 1, 1], [.25, .5, .75, 1.0], Range("[1;4]"))
250	eq(result, (1, 0, 3, [(3, 1.0)]))
251
252	# empty input
253	result = cq([], [.25, .5, .75, 1.0], Range("[1;4]"))
254	eq(result, None)
255
256	# empty range
257	result = cq([1, 2, 3, 4], [.25, .5, .75, 1.0], Range("]0;1["))
258	eq(result, None)
259
260	# empty percentiles
261	self.assertRaises(ValueError, cq, [1, 2, 3, 4], [], Range("]0;1["))
262
263	# single percentile
264	self.assertRaises(ValueError, cq, [1, 2, 3, 4], [.5], Range("[0;4]"))
265
266	# percentile doesn't cover range
267	self.assertRaises(ValueError, cq, [1, 2, 3, 4], [.5,.8], Range("[0;4]"))
268
269	# more percentiles than input
270	result = cq([1], [.5, 1.0], Range("[0;4]"))
271	eq(result, (1, 0, 0, [(0, 1.0)]))
272
273	result = cq([1], [.1, .2, .3, .4, .5, .6, .7, .8, .9, 1.0], Range("[0;4]"))
274	eq(result, (1, 0, 0, [(0, 1.0)]))
275
276	# range smaller than the input
277	result = cq([1, 2, 3, 4], [.5, 1.0], Range("[2;3]"))
278	eq(result, (0, 1, 2, [(1, .5), (2, 1.0)]))
279
280	# range outside the input
281	result = cq([5, 6, 7, 8], [.5, 1.0], Range("[2;3]"))
282	eq(result, None)
283
284	result = cq([1, 1, 1, 1, 1, 1], [.25, .5, .75, 1.0], Range("[1;4]"))
285	eq(result, (1, 0, 5, [(5, 1.0)]))
286
287	result = cq([1, 1, 1, 1, 1, 2, 3], [.25, .5, .75, 1.0], Range("[1;4]"))
288	eq(result, (1, 0, 6,
289	[(4, 0.7142857142857143), # the algorithm generated
290	(5, 0.8571428571428571), # these values, but they are
291	(6, 1.0)])) # right.
292
293	# adjusted quantiles
294	result = cq([1, 1, 1, 1, 1,
295	2, 2, 2, 2, 2,
296	3, 3, 3, 3, 3,
297	4, 4, 4, 4, 4,
298	5, 5, 5, 5, 5],
299	[.12, .24, .36, .50, .62, .76, .88, 1.0], Range("[1;5]"))
300	eq(result, (1, 0, 24, [(4, .2), (9, .4), (14, .6), (19, .8), (24, 1.0)]))
301
302
303	class TestCustomRamp(unittest.TestCase):
304
305	def test_color_interpolation(self):
306	"""Test CustomRamp color interpolation"""
307	start = ClassGroupProperties()
308	start.SetFill(Color(1, 1, 1))
309	start.SetLineColor(Color(0, 0, 0))
310
311	end = ClassGroupProperties()
312	end.SetFill(Color(1, 0, 0))
313	end.SetLineColor(Color(0, 1, 0))
314
315	ramp = CustomRamp(start, end)
316	half = ramp.GetProperties(0.5)
317	self.assertEquals(half.GetFill(), Color(1, 0.5, 0.5))
318	self.assertEquals(half.GetLineColor(), Color(0, 0.5, 0))
319
320	class TestFixedRamp(unittest.TestCase):
321
322	def test(self):
323	eq = self.assertEquals
324
325	for lineColor, lineWidth, fillColor in \
326	[(None, None, None), (Color(1, 1, 1), None, None),
327	(None, 4, None), (None, None, Color(0, 1, 0)),
328	(Color(1, 1, 1), 4, None), (Color(1, 1, 1), None, Color(0, 1, 0)),
329	(None, 4, Color(0, 1, 0)), (Color(1, 1, 1), 4, Color(0, 1, 0))]:
330
331	framp = FixedRamp(GreyRamp, (lineColor, lineWidth, fillColor))
332
333	for i in [0.0, 0.2, 0.4, 0.6, 0.8, 1.0]:
334	props = framp.GetProperties(i)
335	if lineColor: eq(props.GetLineColor(), lineColor)
336	if lineWidth: eq(props.GetLineWidth(), lineWidth)
337	if fillColor: eq(props.GetFill(), fillColor)
338
339	if __name__ == "__main__":
340	unittest.main()
341
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