source: development/pyvolution-1d/test_shallow_water_1d.py @ 3290

import unittest, os
from math import sqrt, pi
from shallow_water_1d import *
from Numeric import allclose, array, zeros, ones, Float, take
from config import g, epsilon

#Variable windfield implemented using functions
#def speed(t,x,y):
def speed(t,x):
    """Large speeds halfway between center and edges
    Low speeds at center and edges
    """

    from math import sqrt, exp, cos, pi

    x = array(x)
    #y = array(y)

    N = len(x)
    s = 0*x  #New array

    for k in range(N):

        #r = sqrt(x[k]**2 + y[k]**2)
        r = x[k]

        factor = exp( -(r-0.15)**2 )

        s[k] = 4000 * factor * (cos(t*2*pi/150) + 2)

    return s


#def scalar_func(t,x,y):
def scalar_func(t,x):
    """Function that returns a scalar.
    Used to test error message when Numeric array is expected
    """

    return 17.7


#def angle(t,x,y):
def angle(t,x):
    """Rotating field
    """
    from math import sqrt, atan, pi

    x = array(x)
    #y = array(y)

    N = len(x)
    a = 0*x  #New array

    for k in range(N):
        #r = sqrt(x[k]**2 + y[k]**2)
        r =x[k]

        #angle = atan(y[k]/x[k])
        angle = atan(1/x[k])

        if x[k] < 0:
            angle+=pi #atan in ]-pi/2; pi/2[

        #Take normal direction
        angle -= pi/2

        #Ensure positive radians
        if angle < 0:
            angle += 2*pi

        a[k] = angle/pi*180

    return a


class TestCase(unittest.TestCase):
    def setUp(self):
        pass

    def tearDown(self):
        pass

    def test_flux_zero_case(self):
        #ql = zeros( 3, Float )
        #qr = zeros( 3, Float )
        ql = zeros( 2, Float )
        qr = zeros( 2, Float )
        
        #normal = zeros( 2, Float )
        zl = zr = 0.
        flux, max_speed = flux_function(1.0, ql, qr, zl, zr)

        #assert allclose(flux, [0,0,0])
        assert allclose(flux, [0,0])
        assert max_speed == 0.
        
    def test_flux_constants(self):
        w = 2.0

        #normal = array([1.,0])
        #ql = array([w, 0, 0])
        #qr = array([w, 0, 0])
        ql = array([w, 0])
        qr = array([w, 0])
        
        zl = zr = 0.
        h = w - (zl+zr)/2

        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(1.0, ql, qr, zl, zr)

        #assert allclose(flux, [0., 0.5*g*h**2, 0.])
        assert allclose(flux, [0., 0.5*g*h**2])
        assert max_speed == sqrt(g*h)
    
    def test_flux1(self):
        #Use data from previous version of pyvolution
        #normal = array([1.,0])
        #ql = array([-0.2, 2, 3])
        #qr = array([-0.2, 2, 3])
        ql = array([-0.2, 2])
        qr = array([-0.2, 2])
        zl = zr = -0.5
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(1.0, ql, qr, zl, zr)
        
        #assert allclose(flux, [2.,13.77433333, 20.])
        assert allclose(flux, [2.,13.77433333])
        assert allclose(max_speed, 8.38130948661)

    def test_flux2(self):
        #Use data from previous version of pyvolution
        """
        2D problem
        normal = array([0., -1.])
        ql = array([-0.075, 2, 3])
        qr = array([-0.075, 2, 3])
        equivlent to solving 1D
        ql = array([-0.075, -3])
        qr = array([-0.075, -3])
        with flux not rotated back
        i.e flux =  [-3.,30.441])
        """
        ql = array([-0.075, -3])
        qr = array([-0.075, -3])
        
        zl = zr = -0.375
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(1.0, ql, qr, zl, zr)
        #assert allclose(flux, [-3.,-20.0, -30.441])
        assert allclose(flux, [-3.,30.441])
        assert allclose(max_speed, 11.7146428199)

        
    def test_flux3(self):
        #def test_flux4(self):
        #Use data from previous version of pyvolution
        """
        change from 3d case with rotation
        normal = array([-sqrt(2)/2, sqrt(2)/2])
        ql = array([-0.34319278, 0.10254161, 0.07273855])
        qr = array([-0.30683287, 0.1071986, 0.05930515])
        to 1d case
        ql = [-0.30683287, -0.03386578]
        qr = [-0.04072675,  0.03883622]
        """
        ql = array([-0.34319278, -0.02107395])
        qr = array([-0.30683287, -0.03386578])

        zl = zr = -0.375
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(1.0, ql, qr, zl, zr)
        #assert allclose(flux, [-0.04072676, -0.07096636, -0.01604364])
        assert allclose(flux, [-0.04072676, 0.03883622])
        assert allclose(max_speed, 1.31414103233)
        
    def test_sw_domain_simple(self):
        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        f=10.0

        points = [a, b, c, d, e, f]
        #bac, bce, ecf, dbe, daf, dae
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)
        domain.check_integrity()

        #for name in ['stage', 'xmomentum', 'ymomentum',
        for name in ['stage', 'xmomentum',
                     'elevation', 'friction']:
            assert domain.quantities.has_key(name)


        #assert domain.get_conserved_quantities(0, edge=1) == 0.
        assert domain.get_conserved_quantities(0, vertex=1) == 0.

    def test_boundary_conditions(self):
        
        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        f=10.0

        points = [a, b, c, d, e, f]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4] ]
        #boundary = { (0, 0): 'Third',
        #             (0, 2): 'First',
        #             (2, 0): 'Second',
        #             (2, 1): 'Second',
        #             (3, 1): 'Second',
        #             (3, 2): 'Third'}

        #there are points -1 segements with edges (0,1) = (left, right)
        boundary = {(0,0): 'Start', (4,1): 'Finish'}
        #boundary = {(0,0): 'exterior', (4,1): 'exterior'}
        #domain = Domain(points, vertices, boundary)
        domain = Domain(points, boundary)
        domain.check_integrity()

        #Sets stages in each interval(element)
        #domain.set_quantity('stage', [[1,2,3], [5,5,5],
        #                             [0,0,9], [-6, 3, 3]])
        domain.set_quantity('stage', [[1,2], [5,5],
                                     [0,0], [-6,3], [3,0]])

        #domain.set_quantity('xmomentum', [[1,1,1], [2,2,2],
        #                                  [3,3,3], [4, 4, 4]])
        domain.set_quantity('xmomentum', [[1,1], [2,2],
                                          [3,3], [4, 4], [5,5]])

        #domain.set_quantity('ymomentum', [[10,10,10], [20,20,20],
        #                                  [30,30,30], [40, 40, 40]])

        #D = Dirichlet_boundary([5,2,1])
        #T = Transmissive_boundary(domain)
        R = Reflective_boundary(domain)
        domain.set_boundary( {'Start': R, 'Finish': R})
        #domain.set_boundary( {'exterior': R, 'exterior': R})

        domain.update_boundary()

        #Stage
        #assert domain.quantities['stage'].boundary_values[0] == 2.5
        assert domain.quantities['stage'].boundary_values[0] ==\
               domain.get_conserved_quantities(0, vertex=0)[0] #Reflective (2.5)
        #assert domain.quantities['stage'].boundary_values[1] == 5. #Dirichlet
        #assert domain.quantities['stage'].boundary_values[2] ==\
        #       domain.get_conserved_quantities(2, edge=0)[0] #Transmissive (4.5)
        #assert domain.quantities['stage'].boundary_values[3] ==\
        #       domain.get_conserved_quantities(2, edge=1)[0] #Transmissive (4.5)
        #assert domain.quantities['stage'].boundary_values[4] ==\
        #       domain.get_conserved_quantities(3, edge=1)[0] #Transmissive (-1.5)
        #assert domain.quantities['stage'].boundary_values[5] ==\
        #       domain.get_conserved_quantities(3, edge=2)[0] #Reflective (-1.5)

        #Xmomentum
        #print 'xmom'
        print domain.quantities['xmomentum'].boundary_values[0]
        assert domain.quantities['xmomentum'].boundary_values[0] == 1.0 #Reflective

        #SHOULDN'T THIS BE -1.0
        
        #assert domain.quantities['xmomentum'].boundary_values[1] == 2. #Dirichlet
        #assert domain.quantities['xmomentum'].boundary_values[2] ==\
        #       domain.get_conserved_quantities(2, edge=0)[1] #Transmissive
        #assert domain.quantities['xmomentum'].boundary_values[3] ==\
        #       domain.get_conserved_quantities(2, edge=1)[1] #Transmissive
        #assert domain.quantities['xmomentum'].boundary_values[4] ==\
        #       domain.get_conserved_quantities(3, edge=1)[1] #Transmissive
        assert domain.quantities['xmomentum'].boundary_values[1] == -5.0  #Reflective

    def test_boundary_conditionsII(self):

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        f=10.0

        points = [a, b, c, d, e, f]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4] ]
        #boundary = { (0, 0): 'Third',
        #             (0, 2): 'First',
        #             (2, 0): 'Second',
        #             (2, 1): 'Second',
        #             (3, 1): 'Second',
        #             (3, 2): 'Third',
        #             (0, 1): 'Internal'}
        

        boundary = {(0,0): 'Start', (1,0) : 'Internal', (4,1): 'Finish'}
        #domain = Domain(points, vertices, boundary)
        domain = Domain(points, boundary)
        domain.check_integrity()


        #domain.set_quantity('stage', [[1,2,3], [5,5,5],
        #                              [0,0,9], [-6, 3, 3]])

        #domain.set_quantity('xmomentum', [[1,1,1], [2,2,2],
        #                                  [3,3,3], [4, 4, 4]])

        #domain.set_quantity('ymomentum', [[10,10,10], [20,20,20],
        #                                  [30,30,30], [40, 40, 40]])

        domain.set_quantity('stage', [[1,2], [5,5],
                                      [0,0], [-6, 3], [3, 0]])

        domain.set_quantity('xmomentum', [[1,1], [2,2],
                                          [3,3], [4, 4], [5, 5]])
        


        #D = Dirichlet_boundary([5,2,1])
        #T = Transmissive_boundary(domain)
        R = Reflective_boundary(domain)
        domain.set_boundary( {'Start': R, 'Finish': R, 'Internal': None})

        domain.update_boundary()
        domain.check_integrity()
    
    def test_compute_fluxes0(self):
        #Do a full triangle and check that fluxes cancel out for
        #the constant stage case

        print 'check min time step in compute fluxes is ok, John'

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        f=10.0
        
        points = [a, b, c, d, e, f]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        domain = Domain(points)
        #domain.set_quantity('stage', [[2,2,2], [2,2,2],
        #                              [2,2,2], [2,2,2]])
        domain.set_quantity('stage', [[2,2], [2,2], [2,2], [2,2], [2,2]])
        domain.check_integrity()

        #assert allclose(domain.neighbours, [[-1,1,-1], [2,3,0], [-1,-1,1],[1,-1,-1]])
        assert allclose(domain.neighbours, [[-1,1], [0,2], [1,3],[2,4], [3,-1]])
        #assert allclose(domain.neighbour_edges, [[-1,2,-1], [2,0,1], [-1,-1,0],[1,-1,-1]])
        #assert allclose(domain.neighbour_edges, [[-1,0], [1,0], [1,0], [1,0], [1,-1]])
        assert allclose(domain.neighbour_vertices, [[-1,0], [1,0], [1,0], [1,0], [1,-1]])

        zl=zr=0. #Assume flat bed

        #Flux across right edge of volume 1
        #normal = domain.get_normal(1,0)
        #ql = domain.get_conserved_quantities(vol_id=1, edge=0)
        #qr = domain.get_conserved_quantities(vol_id=2, edge=2)
        #flux0, max_speed = flux_function(normal, ql, qr, zl, zr)

        #Flux across right edge of element 1
        ql = domain.get_conserved_quantities(vol_id=1, vertex=1)
        qr = domain.get_conserved_quantities(vol_id=2, vertex=0)
        #print 'qr and ql 1'
        #print qr
        #print ql
        flux0, max_speed = flux_function(1.0, ql, qr, zl, zr)

        #Check that flux seen from other triangles is inverse
        tmp = qr; qr=ql; ql=tmp
        #print 'qr and ql 2'
        #print qr
        #print ql
        #normal = domain.get_normal(2,2)
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(-1.0, ql, qr, zl, zr)
        #print 'fluxes'
        #print flux0
        #print flux
        assert allclose(flux + flux0, 0.)

        #Flux across upper edge of volume 1
        #normal = domain.get_normal(1,1)
        #ql = domain.get_conserved_quantities(vol_id=1, edge=1)
        #qr = domain.get_conserved_quantities(vol_id=3, edge=0)
        #flux1, max_speed = flux_function(normal, ql, qr, zl, zr)

        #Flux across left edge of element 1
        #ql = domain.get_conserved_quantities(vol_id=1, edge=0)
        #qr = domain.get_conserved_quantities(vol_id=0, edge=1)
        ql = domain.get_conserved_quantities(vol_id=1, vertex=0)
        qr = domain.get_conserved_quantities(vol_id=0, vertex=1)
        flux1, max_speed = flux_function(-1.0, ql, qr, zl, zr)

        #Check that flux seen from other triangles is inverse
        tmp = qr; qr=ql; ql=tmp
        #normal = domain.get_normal(3,0)
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(1.0, ql, qr, zl, zr)
        assert allclose(flux + flux1, 0.)

        #Flux across lower left hypotenuse of volume 1
        #normal = domain.get_normal(1,2)
        #ql = domain.get_conserved_quantities(vol_id=1, edge=2)
        #qr = domain.get_conserved_quantities(vol_id=0, edge=1)
        #flux2, max_speed = flux_function(normal, ql, qr, zl, zr)

        #Check that flux seen from other triangles is inverse
        #tmp = qr; qr=ql; ql=tmp
        #normal = domain.get_normal(0,1)
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        #assert allclose(flux + flux2, 0.)


        #Scale by edgelengths, add up anc check that total flux is zero
        #e0 = domain.edgelengths[1, 0]
        #e1 = domain.edgelengths[1, 1]
        #e2 = domain.edgelengths[1, 2]

        #assert allclose(e0*flux0+e1*flux1+e2*flux2, 0.)
        print 'flux0',flux0
        print 'flux1',flux1
        assert allclose(flux0+flux1, 0.)

        #Now check that compute_flux yields zeros as well
        domain.compute_fluxes()

        #for name in ['stage', 'xmomentum', 'ymomentum']:
        for name in ['stage', 'xmomentum']:
            #print name, domain.quantities[name].explicit_update
            assert allclose(domain.quantities[name].explicit_update[1], 0)

    def test_compute_fluxes1(self):
        #Use values from previous version

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0
        
        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)
        
        val0 = 2.+2.0/3
        val1 = 4.+4.0/3
        val2 = 8.+2.0/3
        val3 = 2.+8.0/3

        #domain.set_quantity('stage', [[val0, val0, val0], [val1, val1, val1],
        #                              [val2, val2, val2], [val3, val3, val3]])
        domain.set_quantity('stage', [[val0, val0], [val1, val1],
                                      [val2, val2], [val3, val3]])
        stage = domain.get_quantity('stage')
        print stage
        domain.check_integrity()

        zl=zr=0. #Assume flat bed

        #Flux across right edge of volume 1
        #normal = domain.get_normal(1,0)
        #ql = domain.get_conserved_quantities(vol_id=1, edge=0)
        #qr = domain.get_conserved_quantities(vol_id=2, edge=2)
        #flux0, max_speed = flux_function(normal, ql, qr, zl, zr)

        #Flux across right edge of volume 1
        #ql = domain.get_conserved_quantities(vol_id=1, edge=1)
        #qr = domain.get_conserved_quantities(vol_id=2, edge=0)
        ql = domain.get_conserved_quantities(vol_id=1, vertex=1)
        qr = domain.get_conserved_quantities(vol_id=2, vertex=0)
        print 'ql',ql
        print 'qr',qr
        flux0, max_speed = flux_function(1.0, ql, qr, zl, zr)
        print 'flux0',flux0
        print 'max_speed', max_speed
        
        #Check that flux seen from other triangles is inverse
        #tmp = qr; qr=ql; ql=tmp
        #normal = domain.get_normal(3,0)
        #flux, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux, max_speed = flux_function(-1.0, qr, ql, zl, zr)
        print flux0
        print flux
        assert allclose(flux + flux0, 0.)

        #print flux0
        #print max_speed
        #assert allclose(flux0, [-15.3598804, 253.71111111, 0.])
        assert allclose(flux0, [-15.3598804, 253.71111111])
        assert allclose(max_speed, 9.21592824046)


        #Flux across upper edge of volume 1
        #normal = domain.get_normal(1,1)
        #ql = domain.get_conserved_quantities(vol_id=1, edge=1)
        #qr = domain.get_conserved_quantities(vol_id=2, edge=0)
        ql = domain.get_conserved_quantities(vol_id=1, vertex=0)
        qr = domain.get_conserved_quantities(vol_id=0, vertex=1)
        #flux1, max_speed = flux_function(normal, ql, qr, zl, zr)
        flux1, max_speed = flux_function(-1.0, ql, qr, zl, zr)
        #assert allclose(flux1, [2.4098563, 0., 123.04444444])
        print 'flux1', flux1
        assert allclose(flux1, [2.4098563, 0.])
        assert allclose(max_speed, 7.22956891292)

        #Flux across lower left hypotenuse of volume 1
        #normal = domain.get_normal(1,2)
        #ql = domain.get_conserved_quantities(vol_id=1, edge=2)
        #qr = domain.get_conserved_quantities(vol_id=0, edge=1)
        #ql = domain.get_conserved_quantities(vol_id=1, vertex=2)
        #qr = domain.get_conserved_quantities(vol_id=0, vertex=1)
        #flux2, max_speed = flux_function(normal, ql, qr, zl, zr)

        #assert allclose(flux2, [9.63942522, -61.59685738, -61.59685738])
        #assert allclose(max_speed, 7.22956891292)

        #Scale, add up and check that compute_fluxes is correct for vol 1
        #e0 = domain.edgelengths[1, 0]
        #e1 = domain.edgelengths[1, 1]
        #e2 = domain.edgelengths[1, 2]

        #total_flux = -(e0*flux0+e1*flux1+e2*flux2)/domain.areas[1]
        total_flux = -(flux0+flux1)/domain.areas[1]
        #assert allclose(total_flux, [-0.68218178, -166.6, -35.93333333])
        assert allclose(total_flux, [-0.68218178, -166.6])
        


        domain.compute_fluxes()

        #assert allclose(total_flux, domain.explicit_update[1,:])
        for i, name in enumerate(['stage', 'xmomentum', 'ymomentum']):
            assert allclose(total_flux[i],
                            domain.quantities[name].explicit_update[1])

        #assert allclose(domain.explicit_update, [
        #    [0., -69.68888889, -69.68888889],
        #    [-0.68218178, -166.6, -35.93333333],
        #    [-111.77316251, 69.68888889, 0.],
        #    [-35.68522449, 0., 69.68888889]])

        assert allclose(domain.quantities['stage'].explicit_update,
                        [0., -0.68218178, -111.77316251, -35.68522449])
        assert allclose(domain.quantities['xmomentum'].explicit_update,
                        [-69.68888889, -166.6, 69.68888889, 0])
        assert allclose(domain.quantities['ymomentum'].explicit_update,
                        [-69.68888889, -35.93333333, 0., 69.68888889])


        #assert allclose(domain.quantities[name].explicit_update

    def test_catching_negative_heights(self):

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)
        val0 = 2.+2.0/3
        val1 = 4.+4.0/3
        val2 = 8.+2.0/3
        val3 = 2.+8.0/3

        zl=zr=4  #Too large
        #domain.set_quantity('elevation', zl*ones( (4,3) ))
        #domain.set_quantity('stage', [[val0, val0-1, val0-2],
        #                              [val1, val1+1, val1],
        #                              [val2, val2-2, val2],
        #                              [val3-0.5, val3, val3]])
        domain.set_quantity('elevation', zl*ones( (4,2) ))
        domain.set_quantity('stage', [[val0, val0-1],
                                      [val1, val1+1],
                                      [val2, val2-2],
                                      [val3-0.5, val3]])

        #Should fail
        try:
            domain.check_integrity()
        except:
            pass

    def test_initial_condition(self):
        """Test that initial condition is output at time == 0
        """

        from config import g
        import copy

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0, 0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0, 0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        #Set up for a gradient of (3,0) at mid triangle
        #def slope(x, y):
        #    return 3*x
        def slope(x):
            return 3*x

        h = 0.1
        #def stage(x,y):
        #    return slope(x,y)+h
        def stage(x):
            return slope(x)+h

        domain.set_quantity('elevation', slope)
        domain.set_quantity('stage', stage)

        initial_stage = copy.copy(domain.quantities['stage'].vertex_values)

        domain.set_boundary({'exterior': Reflective_boundary(domain)})

        #Evolution
        for t in domain.evolve(yieldstep = 1.0, finaltime = 2.0):
            stage = domain.quantities['stage'].vertex_values

            if t == 0.0:
                assert allclose(stage, initial_stage)
            else:
                assert not allclose(stage, initial_stage)

        os.remove(domain.filename + '.sww')

    #####################################################
    def test_gravity(self):
        #Assuming no friction

        from config import g
        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0, 0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0, 0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        def slope(x):
            return 3*x

        h = 0.1
        #def stage(x,y):
        #    return slope(x,y)+h
        def stage(x):
            return slope(x)+h


        domain.set_quantity('elevation', slope)
        domain.set_quantity('stage', stage)

        for name in domain.conserved_quantities:
            assert allclose(domain.quantities[name].explicit_update, 0)
            assert allclose(domain.quantities[name].semi_implicit_update, 0)

        domain.compute_forcing_terms()

        assert allclose(domain.quantities['stage'].explicit_update, 0)
        assert allclose(domain.quantities['xmomentum'].explicit_update, -g*h*3)
        #assert allclose(domain.quantities['ymomentum'].explicit_update, 0)


    def test_manning_friction(self):
        from config import g

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0, 0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0, 0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        #Set up for a gradient of (3,0) at mid triangle
        def slope(x):
            return 3*x

        h = 0.1
        #def stage(x,y):
        #    return slope(x,y)+h
        def stage(x):
            return slope(x)+h

        eta = 0.07
        domain.set_quantity('elevation', slope)
        domain.set_quantity('stage', stage)
        domain.set_quantity('friction', eta)

        for name in domain.conserved_quantities:
            assert allclose(domain.quantities[name].explicit_update, 0)
            assert allclose(domain.quantities[name].semi_implicit_update, 0)

        domain.compute_forcing_terms()

        assert allclose(domain.quantities['stage'].explicit_update, 0)
        assert allclose(domain.quantities['xmomentum'].explicit_update, -g*h*3)
        #assert allclose(domain.quantities['ymomentum'].explicit_update, 0)

        assert allclose(domain.quantities['stage'].semi_implicit_update, 0)
        assert allclose(domain.quantities['xmomentum'].semi_implicit_update, 0)
        #assert allclose(domain.quantities['ymomentum'].semi_implicit_update, 0)

        #Create some momentum for friction to work with
        domain.set_quantity('xmomentum', 1)
        S = -g * eta**2 / h**(7.0/3)

        domain.compute_forcing_terms()
        assert allclose(domain.quantities['stage'].semi_implicit_update, 0)
        assert allclose(domain.quantities['xmomentum'].semi_implicit_update, S)
        #assert allclose(domain.quantities['ymomentum'].semi_implicit_update, 0)

        #A more complex example
        domain.quantities['stage'].semi_implicit_update[:] = 0.0
        domain.quantities['xmomentum'].semi_implicit_update[:] = 0.0
        #domain.quantities['ymomentum'].semi_implicit_update[:] = 0.0

        #domain.set_quantity('xmomentum', 3)
        domain.set_quantity('xmomentum', 5)
        #domain.set_quantity('ymomentum', 4)

        S = -g * eta**2 * 5 / h**(7.0/3)
        #S = -g * eta**2 / h**(7.0/3)


        domain.compute_forcing_terms()

        assert allclose(domain.quantities['stage'].semi_implicit_update, 0)
        print '5*S', 5*S
        #CHECK THIS TEST 
        print domain.quantities['xmomentum'].semi_implicit_update
        #assert allclose(domain.quantities['xmomentum'].semi_implicit_update, 3*S)
        assert allclose(domain.quantities['xmomentum'].semi_implicit_update, 5*S)
        #assert allclose(domain.quantities['ymomentum'].semi_implicit_update, 4*S)

    def test_constant_wind_stress(self):
        from config import rho_a, rho_w, eta_w
        from math import pi, cos, sin, sqrt

       
        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0, 0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0, 0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)
        
        #Flat surface with 1m of water
        domain.set_quantity('elevation', 0)
        domain.set_quantity('stage', 1.0)
        domain.set_quantity('friction', 0)

        Br = Reflective_boundary(domain)
        domain.set_boundary({'exterior': Br})

        #Setup only one forcing term, constant wind stress
        s = 100
        phi = 135
        domain.forcing_terms = []
        domain.forcing_terms.append( Wind_stress(s, phi) )

        domain.compute_forcing_terms()


        const = eta_w*rho_a/rho_w

        #Convert to radians
        phi = phi*pi/180

        #Compute velocity vector (u, v)
        u = s*cos(phi)
        #v = s*sin(phi)

        #Compute wind stress
        #S = const * sqrt(u**2 + v**2)
        S = const * u
        

        assert allclose(domain.quantities['stage'].explicit_update, 0)
        assert allclose(domain.quantities['xmomentum'].explicit_update, S*u)
        #assert allclose(domain.quantities['ymomentum'].explicit_update, S*v)


    def test_variable_wind_stress(self):
        from config import rho_a, rho_w, eta_w
        from math import pi, cos, sin, sqrt

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0, 0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0, 0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        #Flat surface with 1m of water
        domain.set_quantity('elevation', 0)
        domain.set_quantity('stage', 1.0)
        domain.set_quantity('friction', 0)

        Br = Reflective_boundary(domain)
        domain.set_boundary({'exterior': Br})

        domain.time = 5.54 #Take a random time (not zero)

        #Setup only one forcing term, constant wind stress
        s = 100
        phi = 135
        domain.forcing_terms = []
        domain.forcing_terms.append( Wind_stress(s = speed, phi = angle) )

        domain.compute_forcing_terms()

        #Compute reference solution
        const = eta_w*rho_a/rho_w

        N = domain.number_of_elements

        xc = domain.get_centroid_coordinates()
        t = domain.time

        #x = xc[:,0]
        #y = xc[:,1]
        x = xc
        
        #s_vec = speed(t,x,y)
        #phi_vec = angle(t,x,y)
        s_vec = speed(t,x)
        phi_vec = angle(t,x)


        for k in range(N):
            #Convert to radians
            phi = phi_vec[k]*pi/180
            s = s_vec[k]

            #Compute velocity vector (u, v)
            u = s*cos(phi)
            #v = s*sin(phi)

            #Compute wind stress
            #S = const * sqrt(u**2 + v**2)
            S = const*u

            assert allclose(domain.quantities['stage'].explicit_update[k], 0)
            assert allclose(domain.quantities['xmomentum'].explicit_update[k], S*u)
            #assert allclose(domain.quantities['ymomentum'].explicit_update[k], S*v)

    def test_first_order_extrapolator_const_z(self):

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0, 0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0, 0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        val0 = 2.+2.0/3
        val1 = 4.+4.0/3
        val2 = 8.+2.0/3
        val3 = 2.+8.0/3

        zl=zr=-3.75 #Assume constant bed (must be less than stage)
        #domain.set_quantity('elevation', zl*ones( (4,3) ))
        domain.set_quantity('elevation', zl*ones( (4,2) ))
        #domain.set_quantity('stage', [[val0, val0-1, val0-2],
        #                              [val1, val1+1, val1],
        #                              [val2, val2-2, val2],
        #                              [val3-0.5, val3, val3]])
        domain.set_quantity('stage', [[val0, val0-1],
                                      [val1, val1+1],
                                      [val2, val2-2],
                                      [val3-0.5, val3]])

        domain.order = 1
        domain.distribute_to_vertices_and_edges()

        #Check that centroid values were distributed to vertices
        C = domain.quantities['stage'].centroid_values
        #for i in range(3):
        for i in range(2):
            assert allclose( domain.quantities['stage'].vertex_values[:,i], C)


    def test_first_order_limiter_variable_z(self):
        #Check that first order limiter follows bed_slope
        from Numeric import alltrue, greater_equal
        from config import epsilon

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        val0 = 2.+2.0/3
        val1 = 4.+4.0/3
        val2 = 8.+2.0/3
        val3 = 2.+8.0/3

        #domain.set_quantity('elevation', [[0,0,0], [6,0,0],
        #                                  [6,6,6], [6,6,6]])
        #domain.set_quantity('stage', [[val0, val0, val0],
        #                              [val1, val1, val1],
        #                              [val2, val2, val2],
        #                              [val3, val3, val3]])
        domain.set_quantity('elevation', [[0,0], [6,0],
                                          [6,6], [6,6]])
        domain.set_quantity('stage', [[val0, val0],
                                      [val1, val1],
                                      [val2, val2],
                                      [val3, val3]])

        E = domain.quantities['elevation'].vertex_values
        L = domain.quantities['stage'].vertex_values


        #Check that some stages are not above elevation (within eps)
        #- so that the limiter has something to work with
        assert not alltrue(alltrue(greater_equal(L,E-epsilon)))

        domain.order = 1
        domain.distribute_to_vertices_and_edges()

        #Check that all stages are above elevation (within eps)
        assert alltrue(alltrue(greater_equal(L,E-epsilon)))


#####################################################
    def test_distribute_basic(self):
        #Using test data generated by pyvolution-2
        #Assuming no friction and flat bed (0.0)

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        val0 = 2.
        val1 = 4.
        val2 = 8.
        val3 = 2.

        domain.set_quantity('stage', [val0, val1, val2, val3],
                            location='centroids')
        L = domain.quantities['stage'].vertex_values

        #First order
        domain.order = 1
        domain.distribute_to_vertices_and_edges()
        assert allclose(L[1], val1)

        #Second order
        domain.order = 2
        domain.distribute_to_vertices_and_edges()
        assert allclose(L[1], [2.2, 4.9, 4.9])



    def test_distribute_away_from_bed(self):
        #Using test data generated by pyvolution-2
        #Assuming no friction and flat bed (0.0)

        #a = [0.0, 0.0]
        #b = [0.0, 2.0]
        #c = [2.0,0.0]
        #d = [0.0, 4.0]
        #e = [2.0, 2.0]
        #f = [4.0,0.0]
        a=0.0
        b=2.0
        c=4.0
        d=6.0
        e=8.0
        #f=10.0

        #points = [a, b, c, d, e, f]
        points = [a, b, c, d, e]
        #bac, bce, ecf, dbe
        #vertices = [ [1,0,2], [1,2,4], [4,2,5], [3,1,4]]

        #domain = Domain(points, vertices)
        domain = Domain(points)

        L = domain.quantities['stage'].vertex_values

        #def stage(x,y):
        #    return x**2
        def stage(x):
            return x**2

        domain.set_quantity('stage', stage, location='centroids')

        a = domain.quantities['stage'].compute_gradients()
        print 'a1', a
        ###assert allclose(a[1], 3.33333334)
        #assert allclose(b[1], 0.0)

        domain.order = 1
        domain.distribute_to_vertices_and_edges()
        print 'l',L
        #assert allclose(L[1], 1.77777778)
        assert allclose(L[1], 9)

        domain.order = 2
        domain.distribute_to_vertices_and_edges()
        assert allclose(L[1], [0.57777777, 2.37777778, 2.37777778])





#-------------------------------------------------------------
if __name__ == "__main__":
    suite = unittest.makeSuite(TestCase,'test')
    runner = unittest.TextTestRunner(verbosity=2)
    runner.run(suite)