Adds sol method to the model and removes skipped test

tests/model/test_model.py

@@ -1,7 +1,5 @@
 import numpy
 import pathfinder.model as model
-import scipy.optimize
-import pytest
 
 
 def test_dotdipolemodel_repr():
@@ -49,8 +47,7 @@ def print_result(msg, result):
 		pass
 
 
-@pytest.mark.skip(reason="old")
-def test_dot_dipole_model_jac():
+def test_dot_dipole_model_solution():
 	v1 = -0.05547767706400186526225414
 	v2 = -0.06018573388098888319642888
 	v3 = -0.06364032191901859480476888
@@ -59,6 +56,7 @@ def test_dot_dipole_model_jac():
 	v6 = -0.05735489606460216
 	v7 = -0.07237320672886623
 	v8 = -0.1082531754730548
+	v9 = -0.04471694936155558
 
 	c1 = model.DotMeasurement(v1, [0, 0, 1])
 	c2 = model.DotMeasurement(v2, [0, 0, 2])
@@ -68,61 +66,11 @@ def test_dot_dipole_model_jac():
 	c6 = model.DotMeasurement(v6, [0, 0, 6])
 	c7 = model.DotMeasurement(v7, [1, 1, 7])
 	c8 = model.DotMeasurement(v8, [1, 2, 3])
+	c9 = model.DotMeasurement(v9, [0, -1, 0])
 
-	mod = model.DotDipoleModel([c1, c2, c3, c4, c5, c6], 1)
-	res = scipy.optimize.least_squares(mod.costs(), numpy.array([1, 2, 3, 4, 5, 6]), jac=mod.jac(), ftol=1e-12)
-	print_result("6 dots, least sq", res)
-	mod2 = model.DotDipoleModel([c1, c2, c3, c4, c5, c6, c7, c8], 1)
-	res2 = scipy.optimize.least_squares(mod2.costs(), numpy.array([0, 0, 0, 0, 0, 0]), jac=mod2.jac(), ftol=1e-12, gtol=3e-16)
-	print_result("7 dots, least squares", res2)
-	print(mod2.costs()(res2.x))
-	print(mod2.costs()(numpy.array([1, 3, 5, 5, 6, 7])))
+	expected_result = numpy.array([1, 3, 5, 5, 6, 7])
 
-
-@pytest.mark.skip(reason="bad test")
-def test_dot_2dipoles_model_jac():
-	dots_12andone = [
-		model.DotMeasurement(-0.1978319326584865, [-4, -1, 0]),
-		model.DotMeasurement(-0.1273171638293727, [-4, -5, 0]),
-		model.DotMeasurement(-0.05545025617224288, [-4, -9, 0]),
-		model.DotMeasurement(-0.4960209997369774, [-1, -1, 0]),
-		model.DotMeasurement(-0.1763373289754278, [-1, -5, 0]),
-		model.DotMeasurement(-0.04946346672578462, [-1, -9, 0]),
-		model.DotMeasurement(-0.5633156098386561, [1, -1, 0]),
-		model.DotMeasurement(-0.113765134433174, [1, -5, 0]),
-		model.DotMeasurement(-0.0294893572499722, [1, -9, 0]),
-		model.DotMeasurement(0.7794941616360612, [4, -1, 0]),
-		model.DotMeasurement(0.1110683086477768, [4, -5, 0]),
-		model.DotMeasurement(0.01183272220840589, [4, -9, 0]),
-		model.DotMeasurement(-0.1096485462119833, [1, 1, 1]),
-		model.DotMeasurement(-0.3925851888077783, [1, 1, -1])
-	]
-	# dots = [
-	# 	model.Dot(-0.1978319326584865, [-4, -1, 0]),
-	# 	model.Dot(-0.1273171638293727, [-4, -5, 0]),
-	# 	model.Dot(-0.05545025617224288, [-4, -9, 0]),
-	# 	model.Dot(-0.4960209997369774, [-1, -1, 0]),
-	# 	model.Dot(-0.1763373289754278, [-1, -5, 0]),
-	# 	model.Dot(-0.04946346672578462, [-1, -9, 0]),
-	# 	model.Dot(-0.5633156098386561, [1, -1, 0]),
-	# 	model.Dot(-0.113765134433174, [1, -5, 0]),
-	# 	model.Dot(-0.0294893572499722, [1, -9, 0]),
-	# 	model.Dot(0.7794941616360612, [4, -1, 0]),
-	# 	model.Dot(0.1110683086477768, [4, -5, 0]),
-	# 	model.Dot(0.01183272220840589, [4, -9, 0]),
-	# 	model.Dot(-0.0261092728062841, [-4, -13, 0]),
-	# 	model.Dot(-0.02035559593904894, [-1, -13, 0]),
-	# 	model.Dot(-0.01296894715810522, [1, -13, 0]),
-	# 	model.Dot(0.0003306001626435171, [4, -13, 0]),
-	# 	model.Dot(0.2612817068810759, [7, -1, 0]),
-	# 	model.Dot(0.1203841445911355, [7, -5, 0]),
-	# 	model.Dot(0.03425933872931543, [7, -9, 0]),
-	# 	model.Dot(0.01068547688208644, [7, -13, 0]),
-	# ]
-
-	mod = model.DotDipoleModel(dots_12andone, 2)
-	res = scipy.optimize.least_squares(mod.costs(), numpy.array([0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0]), jac=mod.jac(), ftol=1e-12)
-	print_result("6 dots, least sq", res)
-	print(mod.costs()(res.x))
-	for val in res.x:
-		print(val)
+	mod = model.DotDipoleModel([c1, c2, c3, c4, c5, c6, c7, c8, c9], 1)
+	res = mod.sol()
+	assert res.success, "The solution for a single dipole should have succeeded."
+	numpy.testing.assert_allclose(res.x, expected_result, err_msg="Dipole wasn't as expected.")