def test_events_code_generating(tmpfile):
dsargs, _ = vanDerPol()
dsargs['nobuild'] = True
ev_args = {
'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True
}
ev = Events.makeZeroCrossEvent('y', 0, ev_args, ['y'], targetlang='c')
dsargs['events'] = [ev]
ode = Radau_ODEsystem(dsargs)
ode.makeLibSource(fname=tmpfile)
with open(tmpfile) as g:
code = g.read()
assert 'double monitor(unsigned n_, double t, double *Y_, double *p_, unsigned wkn_, double *wk_, unsigned xvn_, double *xv_);' in code
assert 'int N_EVENTS = 1;' in code
assert 'void assignEvents(EvFunType *events){\n events[0] = &monitor;\n\n}' in code
assert '\n'.join([
'double monitor(unsigned n_, double t, double *Y_, double *p_, unsigned wkn_, double *wk_, unsigned xvn_, double *xv_) {',
'return y; ',
'}']) in code
def test_events_code_generating(tmpfile):
dsargs, _ = vanDerPol()
dsargs['nobuild'] = True
ev_args = {
'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True
}
ev = Events.makeZeroCrossEvent('y', 0, ev_args, ['y'], targetlang='c')
dsargs['events'] = [ev]
ode = Radau_ODEsystem(dsargs)
ode.makeLibSource(fname=tmpfile)
with open(tmpfile) as g:
code = g.read()
assert 'double monitor(unsigned n_, double t, double *Y_, double *p_, unsigned wkn_, double *wk_, unsigned xvn_, double *xv_);' in code
assert 'int N_EVENTS = 1;' in code
assert 'void assignEvents(EvFunType *events){\n events[0] = &monitor;\n\n}' in code
assert '\n'.join([
'double monitor(unsigned n_, double t, double *Y_, double *p_, unsigned wkn_, double *wk_, unsigned xvn_, double *xv_) {',
'return y; ', '}'
]) in code
def dsargs():
timeData = linspace(0, 10, 20)
sindata = sin(20 * timeData)
xData = {'in': sindata}
my_input = InterpolateTable({
'tdata': timeData,
'ics': xData,
'name': 'interp1d',
'method': 'linear',
'checklevel': 1,
'abseps': 1e-5
}).compute('interp')
fvarspecs = {
"w": "k*w + sin(t) + myauxfn1(t)*myauxfn2(w)",
'aux_wdouble': 'w*2 + globalindepvar(t)',
'aux_other': 'myauxfn1(2*t) + initcond(w)'
}
fnspecs = {'myauxfn1': (['t'], '2.5*cos(3*t)'), 'myauxfn2': (['w'], 'w/2')}
# targetlang is optional if the default python target is desired
DSargs = args(fnspecs=fnspecs, name='event_test')
DSargs.varspecs = fvarspecs
DSargs.tdomain = [0.1, 2.1]
DSargs.pars = {'k': 2, 'a': -0.5}
DSargs.vars = 'w'
DSargs.ics = {'w': 3}
DSargs.inputs = {'in': my_input.variables['in']}
DSargs.algparams = {'init_step': 0.01}
DSargs.checklevel = 2
ev_args_nonterm = {
'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True
}
thresh_ev_nonterm = Events.makeZeroCrossEvent('in',
0,
ev_args_nonterm,
inputnames=['in'],
targetlang='c')
ev_args_term = {
'name': 'threshold',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': True,
'precise': True
}
thresh_ev_term = Events.makeZeroCrossEvent('w-20',
1,
ev_args_term, ['w'],
targetlang='c')
DSargs.events = [thresh_ev_nonterm, thresh_ev_term]
return DSargs
def dsargs():
timeData = linspace(0, 10, 20)
sindata = sin(20 * timeData)
xData = {'in': sindata}
my_input = InterpolateTable({
'tdata': timeData,
'ics': xData,
'name': 'interp1d',
'method': 'linear',
'checklevel': 1,
'abseps': 1e-5
}).compute('interp')
fvarspecs = {
"w": "k*w + sin(t) + myauxfn1(t)*myauxfn2(w)",
'aux_wdouble': 'w*2 + globalindepvar(t)',
'aux_other': 'myauxfn1(2*t) + initcond(w)'
}
fnspecs = {
'myauxfn1': (['t'], '2.5*cos(3*t)'),
'myauxfn2': (['w'], 'w/2')
}
# targetlang is optional if the default python target is desired
DSargs = args(fnspecs=fnspecs, name='event_test')
DSargs.varspecs = fvarspecs
DSargs.tdomain = [0.1, 2.1]
DSargs.pars = {'k': 2, 'a': -0.5}
DSargs.vars = 'w'
DSargs.ics = {'w': 3}
DSargs.inputs = {'in': my_input.variables['in']}
DSargs.algparams = {'init_step': 0.01}
DSargs.checklevel = 2
ev_args_nonterm = {
'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True
}
thresh_ev_nonterm = Events.makeZeroCrossEvent(
'in',
0,
ev_args_nonterm,
inputnames=['in'],
targetlang='c'
)
ev_args_term = {
'name': 'threshold',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': True,
'precise': True
}
thresh_ev_term = Events.makeZeroCrossEvent(
'w-20',
1,
ev_args_term,
['w'],
targetlang='c'
)
DSargs.events = [thresh_ev_nonterm, thresh_ev_term]
return DSargs
def test_vode_events_compare_with_euler():
"""
Test terminal and non-terminal event testing with VODE integrator,
including some comparisons and tests of Euler integrator too.
"""
DSargs = args(varspecs={'w': 'k*sin(2*t) - w'}, name='ODEtest')
DSargs.tdomain = [0, 10]
DSargs.pars = {'k': 1, 'p_thresh': -0.25}
DSargs.algparams = {'init_step': 0.001, 'atol': 1e-12, 'rtol': 1e-13}
DSargs.checklevel = 2
DSargs.ics = {'w': -1.0}
DSargs.tdata = [0, 10]
ev_args_nonterm = {'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True}
thresh_ev_nonterm = Events.makeZeroCrossEvent('w', 0,
ev_args_nonterm, varnames=['w'])
ev_args_term = {'name': 'threshold',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': True,
'precise': True}
thresh_ev_term = Events.makeZeroCrossEvent('w-p_thresh',
-1, ev_args_term, varnames=['w'], parnames=['p_thresh'])
DSargs.events = [thresh_ev_nonterm, thresh_ev_term]
testODE = Vode_ODEsystem(DSargs)
# diagnostics and other possible user-defined python functions
# for python solvers only (currently only Euler)
# def before_func(euler):
# print(euler.algparams['init_step'])
#
# def after_func(euler):
# print(euler._solver.y)
#
##DSargs.user_func_beforestep = before_func
##DSargs.user_func_afterstep = after_func
testODE_Euler = Euler_ODEsystem(DSargs)
traj = testODE.compute('traj')
traj2 = testODE_Euler.compute('traj')
pts = traj.sample()
testODE.diagnostics.showWarnings()
mon_evs_found = testODE.getEvents('monitor')
term_evs_found = testODE.getEvents('threshold')
# test Euler
assert allclose(array(testODE.getEventTimes('monitor')),
array(traj2.getEventTimes('monitor')), atol=1e-3)
assert all(traj.getEvents('monitor') == mon_evs_found)
assert all(traj.getEventTimes('threshold')
== testODE.getEventTimes('threshold'))
term_evs_found.info()
# Alternative way to extract events: they are labelled in the
# pointset! These return dictionaries indexing into the pointset.
mon_evs_dict = pts.labels.by_label['Event:monitor']
mon_ev_points = pts[sort(list(mon_evs_dict.keys()))]
assert len(mon_evs_found) == len(mon_ev_points) == 2
assert all(mon_evs_found == mon_ev_points)
def test_vode_events_with_external_input(my_input):
"""
Test Vode_ODEsystem with events involving external inputs.
Robert Clewley, September 2006.
"""
xs = ['x1', 'x2', 'x3']
ys = [0, 0.5, 1]
fvarspecs = {"w": "k*w + pcwfn(sin(t)) + myauxfn1(t)*myauxfn2(w)",
'aux_wdouble': 'w*2 + globalindepvar(t)',
'aux_other': 'myauxfn1(2*t) + initcond(w)'}
fnspecs = {'myauxfn1': (['t'], '2.5*cos(3*t)'),
'myauxfn2': (['w'], 'w/2'),
'pcwfn': makeMultilinearRegrFn('x', xs, ys)}
# targetlang is optional if the default python target is desired
DSargs = args(fnspecs=fnspecs, name='ODEtest')
DSargs.varspecs = fvarspecs
DSargs.tdomain = [0.1, 2.1]
DSargs.pars = {'k': 2, 'a': -0.5, 'x1': -3, 'x2': 0.5, 'x3': 1.5}
DSargs.vars = 'w'
DSargs.inputs = {'in': my_input.variables['example_input']}
DSargs.algparams = {'init_step': 0.01}
DSargs.checklevel = 2
testODE = Vode_ODEsystem(DSargs)
assert not testODE.defined
testODE.set(ics={'w': 3.0},
tdata=[0.11, 2.1])
traj1 = testODE.compute('traj1')
assert testODE.defined
assert_almost_equal(traj1(0.5, 'w'), 8.9771499, 5)
assert not testODE.diagnostics.hasWarnings()
assert_almost_equal(traj1(0.2, ['aux_other']), 3.905819936, 5)
print("\nNow adding a terminating co-ordinate threshold event")
print(" and non-terminating timer event")
# Show off the general-purpose, language-independent event creator:
# 'makeZeroCrossEvent'
ev_args_nonterm = {'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True}
thresh_ev_nonterm = Events.makeZeroCrossEvent('in', 0,
ev_args_nonterm, inputnames=['in'])
# Now show use of the python-target specific creator:
# 'makePythonStateZeroCrossEvent', which is also only
# able to make events for state variable threshold crossings
ev_args_term = {'name': 'threshold',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': True,
'precise': True}
thresh_ev_term = Events.makePythonStateZeroCrossEvent('w',
20, 1, ev_args_term)
testODE.eventstruct.add([thresh_ev_nonterm, thresh_ev_term])
print("Recomputing trajectory:")
print("traj2 = testODE.compute('traj2')")
traj2 = testODE.compute('traj2')
print("\ntestODE.diagnostics.showWarnings() => ")
testODE.diagnostics.showWarnings()
print("\ntraj2.indepdomain.get() => ", traj2.indepdomain.get())
indep1 = traj2.indepdomain[1]
assert indep1 < 1.17 and indep1 > 1.16
mon_evs_found = testODE.getEvents('monitor')
assert len(mon_evs_found) == 1
def _makeBoundsEvents(self,
precise=True,
eventtol=1e-6,
activatedbounds=None):
events = []
# pars + vars (pars used only by PyCont during continuation)
alldoms = copy(self._pdomain)
alldoms.update(self._xdomain)
allnames = self.funcspec.vars + self.funcspec.pars
if activatedbounds is None:
activatedbounds = {}.fromkeys(allnames, (True, True))
for xname, xdom in alldoms.iteritems():
if xname not in allnames:
# don't make bound constraints for non-state variables
continue
xdlo = xdom[0]
xdhi = xdom[1]
evname = xname + "_domlo"
evargs = {
'term': True,
'precise': precise,
'name': evname,
'eventtol': eventtol,
'eventdelay': eventtol * 10,
'eventinterval': eventtol * 20,
'xdomain': self._xdomain,
'pdomain': self._pdomain
}
try:
evargs['active'] = activatedbounds[xname][0] and isfinite(xdlo)
except KeyError:
evargs['active'] = False
evstr = xname + '-' + 'getbound("%s", 0)' % xname
ev = Events.makeZeroCrossEvent(evstr,
-1,
evargs, [xname],
targetlang=self.funcspec.targetlang,
reuseterms=self.funcspec.reuseterms)
events.append(ev)
evname = xname + "_domhi"
evargs = {
'term': True,
'precise': precise,
'name': evname,
'eventtol': eventtol,
'eventdelay': eventtol * 10,
'eventinterval': eventtol * 20,
'xdomain': self._xdomain,
'pdomain': self._pdomain
}
try:
evargs['active'] = activatedbounds[xname][1] and isfinite(xdhi)
except KeyError:
evargs['active'] = False
evstr = xname + '-' + 'getbound("%s", 1)' % xname
ev = Events.makeZeroCrossEvent(evstr,
1,
evargs, [xname],
targetlang=self.funcspec.targetlang,
reuseterms=self.funcspec.reuseterms)
events.append(ev)
if events != []:
self._addEvents(events)
def test_vode_events_compare_with_euler():
"""
Test terminal and non-terminal event testing with VODE integrator,
including some comparisons and tests of Euler integrator too.
"""
DSargs = args(varspecs={'w': 'k*sin(2*t) - w'}, name='ODEtest')
DSargs.tdomain = [0, 10]
DSargs.pars = {'k': 1, 'p_thresh': -0.25}
DSargs.algparams = {'init_step': 0.001, 'atol': 1e-12, 'rtol': 1e-13}
DSargs.checklevel = 2
DSargs.ics = {'w': -1.0}
DSargs.tdata = [0, 10]
ev_args_nonterm = {'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True}
thresh_ev_nonterm = Events.makeZeroCrossEvent('w', 0,
ev_args_nonterm, varnames=['w'])
ev_args_term = {'name': 'threshold',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': True,
'precise': True}
thresh_ev_term = Events.makeZeroCrossEvent('w-p_thresh',
-1, ev_args_term, varnames=['w'], parnames=['p_thresh'])
DSargs.events = [thresh_ev_nonterm, thresh_ev_term]
testODE = Vode_ODEsystem(DSargs)
# diagnostics and other possible user-defined python functions
# for python solvers only (currently only Euler)
# def before_func(euler):
# print(euler.algparams['init_step'])
#
# def after_func(euler):
# print(euler._solver.y)
#
##DSargs.user_func_beforestep = before_func
##DSargs.user_func_afterstep = after_func
testODE_Euler = Euler_ODEsystem(DSargs)
traj = testODE.compute('traj')
traj2 = testODE_Euler.compute('traj')
pts = traj.sample()
testODE.diagnostics.showWarnings()
mon_evs_found = testODE.getEvents('monitor')
term_evs_found = testODE.getEvents('threshold')
# test Euler
assert allclose(array(testODE.getEventTimes('monitor')),
array(traj2.getEventTimes('monitor')), atol=1e-3)
assert all(traj.getEvents('monitor') == mon_evs_found)
assert all(traj.getEventTimes('threshold')
== testODE.getEventTimes('threshold'))
term_evs_found.info()
# Alternative way to extract events: they are labelled in the
# pointset! These return dictionaries indexing into the pointset.
mon_evs_dict = pts.labels.by_label['Event:monitor']
mon_ev_points = pts[sort(mon_evs_dict.keys())]
assert len(mon_evs_found) == len(mon_ev_points) == 2
assert all(mon_evs_found == mon_ev_points)
def test_vode_events_with_external_input(my_input):
"""
Test Vode_ODEsystem with events involving external inputs.
Robert Clewley, September 2006.
"""
xs = ['x1', 'x2', 'x3']
ys = [0, 0.5, 1]
fvarspecs = {"w": "k*w + pcwfn(sin(t)) + myauxfn1(t)*myauxfn2(w)",
'aux_wdouble': 'w*2 + globalindepvar(t)',
'aux_other': 'myauxfn1(2*t) + initcond(w)'}
fnspecs = {'myauxfn1': (['t'], '2.5*cos(3*t)'),
'myauxfn2': (['w'], 'w/2'),
'pcwfn': makeMultilinearRegrFn('x', xs, ys)}
# targetlang is optional if the default python target is desired
DSargs = args(fnspecs=fnspecs, name='ODEtest')
DSargs.varspecs = fvarspecs
DSargs.tdomain = [0.1, 2.1]
DSargs.pars = {'k': 2, 'a': -0.5, 'x1': -3, 'x2': 0.5, 'x3': 1.5}
DSargs.vars = 'w'
DSargs.inputs = {'in': my_input.variables['example_input']}
DSargs.algparams = {'init_step': 0.01}
DSargs.checklevel = 2
testODE = Vode_ODEsystem(DSargs)
assert not testODE.defined
testODE.set(ics={'w': 3.0},
tdata=[0.11, 2.1])
traj1 = testODE.compute('traj1')
assert testODE.defined
assert_almost_equal(traj1(0.5, 'w'), 8.9771499, 5)
assert not testODE.diagnostics.hasWarnings()
assert_almost_equal(traj1(0.2, ['aux_other']), 3.905819936, 5)
print("\nNow adding a terminating co-ordinate threshold event")
print(" and non-terminating timer event")
# Show off the general-purpose, language-independent event creator:
# 'makeZeroCrossEvent'
ev_args_nonterm = {'name': 'monitor',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': False,
'precise': True}
thresh_ev_nonterm = Events.makeZeroCrossEvent('in', 0,
ev_args_nonterm, inputnames=['in'])
# Now show use of the python-target specific creator:
# 'makePythonStateZeroCrossEvent', which is also only
# able to make events for state variable threshold crossings
ev_args_term = {'name': 'threshold',
'eventtol': 1e-4,
'eventdelay': 1e-5,
'starttime': 0,
'active': True,
'term': True,
'precise': True}
thresh_ev_term = Events.makePythonStateZeroCrossEvent('w',
20, 1, ev_args_term)
testODE.eventstruct.add([thresh_ev_nonterm, thresh_ev_term])
print("Recomputing trajectory:")
print("traj2 = testODE.compute('traj2')")
traj2 = testODE.compute('traj2')
print("\ntestODE.diagnostics.showWarnings() => ")
testODE.diagnostics.showWarnings()
print("\ntraj2.indepdomain.get() => ", traj2.indepdomain.get())
indep1 = traj2.indepdomain[1]
assert indep1 < 1.17 and indep1 > 1.16
mon_evs_found = testODE.getEvents('monitor')
assert len(mon_evs_found) == 1
