Quadrants test in PyClaw
#!/usr/bin/env python
# encoding: utf-8
"""
Solve the Euler equations of compressible fluid dynamics.
"""
from clawpack import pyclaw
from clawpack import riemann
solver = pyclaw.ClawSolver2D(riemann.rp2_euler_4wave)
solver.all_bcs = pyclaw.BC.extrap
domain = pyclaw.Domain([0.,0.],[1.,1.],[512,512])
solution = pyclaw.Solution(solver.num_eqn,domain)
gamma = 1.4
solution.problem_data['gamma'] = gamma
solver.dimensional_split = False
solver.transverse_waves = 2
# Set initial data
xx,yy = domain.grid.p_centers
l = xx<0.8; r = xx>=0.8; b = yy<0.8; t = yy>=0.8
solution.q[0,...] = 1.5*r*t + 0.532258064516129*l*t + 0.137992831541219*l*b + 0.532258064516129*r*b
u = 0.*r*t + 1.206045378311055*l*t + 1.206045378311055*l*b + 0.*r*b
v = 0.*r*t + 0.*l*t + 1.206045378311055*l*b + 1.206045378311055*r*b
p = 1.5*r*t + 0.3*l*t + 0.029032258064516*l*b + 0.3*r*b
solution.q[1,...] = solution.q[0,...] * u
solution.q[2,...] = solution.q[0,...] * v
solution.q[3,...] = 0.5*solution.q[0,...]*(u**2+v**2) + p/(gamma-1.)
#solver.evolve_to_time(solution,tend=0.3)
claw = pyclaw.Controller()
claw.tfinal = 0.8
claw.solution = solution
claw.solver = solver
status = claw.run()