def test__insert_input_files(self):
# A new input record is inserted for the GMPE logic tree but the
# existing input row is reused for the source model logic tree.
engine._insert_input_files(self.PARAMS, self.job, False)
[glt_i] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertNotEqual(self.glt_i.id, glt_i.id)
[slt_i] = models.inputs4job(self.job.id, input_type="lt_source")
self.assertEqual(self.slt_i.id, slt_i.id)
def test_model_content_many_files(self):
slt_content = open(self.SLT, 'r').read()
glt_content = open(self.GLT, 'r').read()
engine._insert_input_files(self.PARAMS, self.job, True)
[slt] = models.inputs4job(self.job.id, input_type="lt_source")
[glt] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertEqual('xml', slt.model_content.content_type)
self.assertEqual(slt_content, slt.model_content.raw_content)
self.assertEqual('xml', glt.model_content.content_type)
self.assertEqual(glt_content, glt.model_content.raw_content)
def test_model_content_many_files(self):
slt_content = open(self.SLT, 'r').read()
glt_content = open(self.GLT, 'r').read()
engine._insert_input_files(self.PARAMS, self.job, True)
[slt] = models.inputs4job(self.job.id, input_type="lt_source")
[glt] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertEqual('xml', slt.model_content.content_type)
self.assertEqual(slt_content, slt.model_content.raw_content)
self.assertEqual('xml', glt.model_content.content_type)
self.assertEqual(glt_content, glt.model_content.raw_content)
def test__insert_input_files(self):
# A new input record is inserted for the GMPE logic tree but the
# existing input row is reused for the source model logic tree.
engine._insert_input_files(self.PARAMS, self.job, False)
[glt_i] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertNotEqual(self.glt_i.id, glt_i.id)
[slt_i] = models.inputs4job(self.job.id, input_type="lt_source")
self.assertEqual(self.slt_i.id, slt_i.id)
# Make sure the LT and the hazard source have been associated.
[src_link] = models.Src2ltsrc.objects.filter(lt_src=slt_i)
self.assertEqual("dissFaultModel.xml", src_link.filename)
self.assertEqual(slt_i, src_link.lt_src)
[hzrd_i] = models.inputs4job(self.job.id, input_type="source")
self.assertEqual(hzrd_i, src_link.hzrd_src)
def test__insert_input_files(self):
# A new input record is inserted for the GMPE logic tree but the
# existing input row is reused for the source model logic tree.
engine._insert_input_files(self.PARAMS, self.job, False)
[glt_i] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertNotEqual(self.glt_i.id, glt_i.id)
[slt_i] = models.inputs4job(self.job.id, input_type="lt_source")
self.assertEqual(self.slt_i.id, slt_i.id)
# Make sure the LT and the hazard source have been associated.
[src_link] = models.Src2ltsrc.objects.filter(lt_src=slt_i)
self.assertEqual("dissFaultModel.xml", src_link.filename)
self.assertEqual(slt_i, src_link.lt_src)
[hzrd_i] = models.inputs4job(self.job.id, input_type="source")
self.assertEqual(hzrd_i, src_link.hzrd_src)
def make_assets(self):
[ism] = models.inputs4job(self.job.id, input_type="exposure")
em = models.ExposureModel(
owner=ism.owner, input=ism,
name="AAA", category="single_asset",
reco_type="aggregated", reco_unit="USD",
stco_type="aggregated", stco_unit="USD")
em.save()
site_1 = shapes.Site(-116.0, 41.0)
site_2 = shapes.Site(-117.0, 42.0)
asset_1 = models.ExposureData(
exposure_model=em, taxonomy="RC",
asset_ref="asset_1", number_of_units=100, stco=1,
site=geos.GEOSGeometry(site_1.point.to_wkt()), reco=1)
asset_2 = models.ExposureData(
exposure_model=em, taxonomy="RM",
asset_ref="asset_2", number_of_units=40, stco=1,
site=geos.GEOSGeometry(site_2.point.to_wkt()), reco=1)
asset_3 = models.ExposureData(
exposure_model=em, taxonomy="RM",
asset_ref="asset_3", number_of_units=40, stco=1,
site=geos.GEOSGeometry(site_2.point.to_wkt()), reco=1)
asset_1.save()
asset_2.save()
asset_3.save()
return asset_1, asset_2, asset_3
def store_exposure_assets(job_id, base_path):
"""
Load exposure assets from input file and store them
into database.
If the given job already has an input of type `exposure`,
this function simply returns without doing anything.
:param job_id: the id of the job where the assets
belong to.
:type job_id: integer
:param base_path: the path where the application has been
triggered. It is used to properly locate the input
files, that are stored with a relative path.
:type base_path: string
"""
[emi] = models.inputs4job(job_id, "exposure")
if emi.exposuremodel_set.all().count() > 0:
return
path = os.path.join(base_path, emi.path)
exposure_parser = exposure.ExposureModelFile(path)
writer = ExposureDBWriter(emi)
writer.serialize(exposure_parser)
def ln_input2job(path, input_type):
"""Link identical or newly created input to the given job."""
digest = _file_digest(path)
linked_inputs = inputs4job(job.id)
if any(li.digest == digest and li.input_type == input_type
for li in linked_inputs):
return
in_model = (_identical_input(input_type, digest, job.owner.id)
if not force_inputs else None)
if in_model is None:
# Save the raw input file contents to the DB:
model_content = ModelContent()
with open(path, 'rb') as fh:
model_content.raw_content = fh.read()
# Try to guess the content type:
model_content.content_type = _get_content_type(path)
model_content.save()
in_model = Input(path=path, input_type=input_type, owner=job.owner,
size=os.path.getsize(path), digest=digest,
model_content=model_content)
in_model.save()
# Make sure we don't link to the same input more than once.
if in_model.id not in inputs_seen:
inputs_seen.add(in_model.id)
i2j = Input2job(input=in_model, oq_job=job)
i2j.save()
return in_model
def test_inputs4job_with_single_input(self):
# The single input is returned.
inp = models.Input(owner=self.job.owner, path=self.paths.next(),
input_type="exposure", size=self.sizes.next())
inp.save()
models.Input2job(oq_job=self.job, input=inp).save()
self.assertEqual([inp], models.inputs4job(self.job.id))
def ln_input2job(path, input_type):
"""Link identical or newly created input to the given job."""
digest = _file_digest(path)
linked_inputs = inputs4job(job.id)
if any(li.digest == digest and li.input_type == input_type
for li in linked_inputs):
return
in_model = (_identical_input(input_type, digest, job.owner.id)
if not force_inputs else None)
if in_model is None:
# Save the raw input file contents to the DB:
model_content = ModelContent()
with open(path, 'rb') as fh:
model_content.raw_content = fh.read()
# Try to guess the content type:
model_content.content_type = _get_content_type(path)
model_content.save()
in_model = Input(path=path,
input_type=input_type,
owner=job.owner,
size=os.path.getsize(path),
digest=digest,
model_content=model_content)
in_model.save()
# Make sure we don't link to the same input more than once.
if in_model.id not in inputs_seen:
inputs_seen.append(in_model.id)
i2j = Input2job(input=in_model, oq_job=job)
i2j.save()
return in_model
def test_inputs4job_with_correct_input_type_and_path(self):
# The source inputs are returned.
inp1 = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="source",
size=self.sizes.next())
inp1.save()
models.Input2job(oq_job=self.job, input=inp1).save()
path = self.paths.next()
inp2 = models.Input(owner=self.job.owner,
path=path,
input_type="source",
size=self.sizes.next())
inp2.save()
models.Input2job(oq_job=self.job, input=inp2).save()
inp3 = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="source",
size=self.sizes.next())
inp3.save()
models.Input2job(oq_job=self.job, input=inp3).save()
self.assertEqual([inp2],
models.inputs4job(self.job.id,
input_type="source",
path=path))
def setUpClass(cls):
cls.job = engine.prepare_job()
jp, _, _ = engine.import_job_profile(RISK_DEMO_CONFIG_FILE, cls.job)
calc_proxy = helpers.create_job({}, job_id=cls.job.id,
oq_job_profile=jp, oq_job=cls.job)
# storing the basic exposure model
ClassicalRiskCalculator(calc_proxy).store_exposure_assets()
[em_input] = models.inputs4job(cls.job.id, input_type="exposure")
[model] = em_input.exposuremodel_set.all()
site = shapes.Site(1.0, 2.0)
# more assets at same location
models.ExposureData(
exposure_model=model, taxonomy="NOT_USED",
asset_ref="ASSET_1", stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()), reco=1).save()
models.ExposureData(
exposure_model=model, taxonomy="NOT_USED",
asset_ref="ASSET_2", stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()), reco=1).save()
site = shapes.Site(2.0, 2.0)
# just one asset at location
models.ExposureData(
exposure_model=model, taxonomy="NOT_USED",
asset_ref="ASSET_3", stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()), reco=1).save()
def _store_dsc_fmodel(self):
[ism] = models.inputs4job(self.job.id, input_type="fragility")
fmodel = models.FragilityModel(
owner=ism.owner, input=ism, imls=[0.1, 0.3, 0.5, 0.7],
imt="mmi", lss=["LS1", "LS2"], format="discrete",
no_damage_limit=0.05)
fmodel.save()
models.Ffd(
fragility_model=fmodel, taxonomy="RC",
ls="LS2", poes=[0.00, 0.05, 0.20, 0.50], lsi=2).save()
models.Ffd(
fragility_model=fmodel, taxonomy="RC",
ls="LS1", poes=[0.05, 0.20, 0.50, 1.00], lsi=1).save()
models.Ffd(
fragility_model=fmodel, taxonomy="RM",
ls="LS2", poes=[0.02, 0.07, 0.25, 0.60], lsi=2).save()
models.Ffd(
fragility_model=fmodel, taxonomy="RM",
ls="LS1", poes=[0.03, 0.12, 0.42, 0.90], lsi=1).save()
return fmodel
def setUpClass(cls):
cls.job = engine.prepare_job()
jp, _, _ = engine.import_job_profile(RISK_DEMO_CONFIG_FILE, cls.job)
cls.job_ctxt = helpers.create_job({},
job_id=cls.job.id,
oq_job_profile=jp,
oq_job=cls.job)
calc = ClassicalRiskCalculator(cls.job_ctxt)
calc.store_exposure_assets()
[input] = models.inputs4job(cls.job.id, input_type="exposure")
model = input.model()
assets = model.exposuredata_set.filter(taxonomy="af/ctc-D/LR")
# Add some more assets.
coos = [(10.000155392289116, 46.546194318563),
(10.222034128255, 46.0071299176413),
(10.520376165581, 46.247463385278)]
for lat, lon in coos:
site = shapes.Site(lat, lon)
cls.sites.append(site)
if assets:
continue
location = geos.GEOSGeometry(site.point.to_wkt())
asset = models.ExposureData(exposure_model=model,
taxonomy="af/ctc-D/LR",
asset_ref=helpers.random_string(6),
stco=lat * 2,
site=location,
reco=1.1 * lon)
asset.save()
def test_dda_iml_above_range(self):
# corner case where we have a ground motion value
# (that corresponds to the intensity measure level in the
# fragility function) that is higher than the highest
# intensity measure level defined in the model (in this
# particular case 0.7). Given this condition, to compute
# the fractions of buildings we use the highest intensity
# measure level defined in the model (0.7 in this case)
[ism] = models.inputs4job(self.job.id, input_type="fragility")
fmodel = models.FragilityModel(
owner=ism.owner, input=ism, imls=[0.1, 0.3, 0.5, 0.7],
imt="mmi", lss=["LS1"], format="discrete")
fmodel.save()
func = models.Ffd(
fragility_model=fmodel, taxonomy="RC",
ls="LS1", poes=[0.05, 0.20, 0.50, 1.00], lsi=1)
func.save()
self._close_to(compute_gmv_fractions([func], 0.7),
compute_gmv_fractions([func], 0.8))
def test_inputs4job_with_wrong_path(self):
# No input is returned.
inp = models.Input(owner=self.job.owner, path=self.paths.next(),
input_type="exposure", size=self.sizes.next())
inp.save()
models.Input2job(oq_job=self.job, input=inp).save()
self.assertEqual([], models.inputs4job(self.job.id, path="xyz"))
def store_exposure_assets(job_id, base_path):
"""
Load exposure assets from input file and store them
into database.
If the given job already has an input of type `exposure`,
this function simply returns without doing anything.
:param job_id: the id of the job where the assets
belong to.
:type job_id: integer
:param base_path: the path where the application has been
triggered. It is used to properly locate the input
files, that are stored with a relative path.
:type base_path: string
"""
[emi] = models.inputs4job(job_id, "exposure")
if emi.exposuremodel_set.all().count() > 0:
return
path = os.path.join(base_path, emi.path)
exposure_parser = exposure.ExposureModelFile(path)
writer = ExposureDBWriter(emi)
writer.serialize(exposure_parser)
def setUpClass(cls):
cls.job = engine.prepare_job()
jp, _, _ = engine.import_job_profile(RISK_DEMO_CONFIG_FILE, cls.job)
cls.job_ctxt = helpers.create_job({}, job_id=cls.job.id,
oq_job_profile=jp, oq_job=cls.job)
calc = ClassicalRiskCalculator(cls.job_ctxt)
calc.store_exposure_assets()
[input] = models.inputs4job(cls.job.id, input_type="exposure")
model = input.model()
assets = model.exposuredata_set.filter(taxonomy="af/ctc-D/LR")
# Add some more assets.
coos = [(10.000155392289116, 46.546194318563),
(10.222034128255, 46.0071299176413),
(10.520376165581, 46.247463385278)]
for lat, lon in coos:
site = shapes.Site(lat, lon)
cls.sites.append(site)
if assets:
continue
location = geos.GEOSGeometry(site.point.to_wkt())
asset = models.ExposureData(
exposure_model=model, taxonomy="af/ctc-D/LR",
asset_ref=helpers.random_string(6), stco=lat * 2,
site=location, reco=1.1 * lon)
asset.save()
def make_assets(self):
[ism] = models.inputs4job(self.job.id, input_type="exposure")
em = models.ExposureModel(
owner=ism.owner, input=ism,
name="AAA", category="single_asset",
reco_type="aggregated", reco_unit="USD",
stco_type="aggregated", stco_unit="USD")
em.save()
site_1 = shapes.Site(-116.0, 41.0)
site_2 = shapes.Site(-117.0, 42.0)
asset_1 = models.ExposureData(
exposure_model=em, taxonomy="RC",
asset_ref="asset_1", number_of_units=100, stco=1,
site=geos.GEOSGeometry(site_1.point.to_wkt()), reco=1)
asset_2 = models.ExposureData(
exposure_model=em, taxonomy="RM",
asset_ref="asset_2", number_of_units=40, stco=1,
site=geos.GEOSGeometry(site_2.point.to_wkt()), reco=1)
asset_3 = models.ExposureData(
exposure_model=em, taxonomy="RM",
asset_ref="asset_3", number_of_units=40, stco=1,
site=geos.GEOSGeometry(site_2.point.to_wkt()), reco=1)
asset_1.save()
asset_2.save()
asset_3.save()
return asset_1, asset_2, asset_3
def _store_con_fmodel(self):
[ism] = models.inputs4job(self.job.id, input_type="fragility")
fmodel = models.FragilityModel(
owner=ism.owner, input=ism,
lss=["LS1", "LS2"], format="continuous")
fmodel.save()
models.Ffc(
fragility_model=fmodel, taxonomy="RC",
ls="LS2", mean="0.35", stddev="0.10", lsi=2).save()
models.Ffc(
fragility_model=fmodel, taxonomy="RC",
ls="LS1", mean="0.20", stddev="0.05", lsi=1).save()
models.Ffc(
fragility_model=fmodel, taxonomy="RM",
ls="LS2", mean="0.40", stddev="0.12", lsi=2).save()
models.Ffc(
fragility_model=fmodel, taxonomy="RM",
ls="LS1", mean="0.25", stddev="0.08", lsi=1).save()
return fmodel
def test_dda_iml_below_range_damage_limit_defined(self):
# corner case where we have a ground motion value
# (that corresponds to the intensity measure level in the
# fragility function) that is lower than the lowest
# intensity measure level defined in the model (in this
# particular case 0.1) and lower than the no_damage_limit
# attribute defined in the model. Given this condition, the
# fractions of buildings is 100% no_damage and 0% for the
# remaining limit states defined in the model.
[ism] = models.inputs4job(self.job.id, input_type="fragility")
fmodel = models.FragilityModel(
owner=ism.owner, input=ism, imls=[0.1, 0.3, 0.5, 0.7],
imt="mmi", lss=["LS1"], format="discrete", no_damage_limit=0.05)
fmodel.save()
func = models.Ffd(
fragility_model=fmodel, taxonomy="RC",
ls="LS1", poes=[0.05, 0.20, 0.50, 1.00], lsi=1)
func.save()
self._close_to([1.0, 0.0],
compute_gmv_fractions([func], 0.02))
def setUpClass(cls):
cls.job = engine.prepare_job()
jp, _, _ = engine.import_job_profile(RISK_DEMO_CONFIG_FILE, cls.job)
calc_proxy = helpers.create_job({}, job_id=cls.job.id,
oq_job_profile=jp, oq_job=cls.job)
# storing the basic exposure model
ClassicalRiskCalculator(calc_proxy).store_exposure_assets()
[input] = models.inputs4job(cls.job.id, input_type="exposure")
model = input.model()
assets = model.exposuredata_set.filter(taxonomy="aa/aatc-D/LR")
if not assets:
# This model did not exist in the database before.
site = shapes.Site(1.0, 2.0)
# more assets at same location
models.ExposureData(
exposure_model=model, taxonomy="aa/aatc-D/LR",
asset_ref="ASSET_1", stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()), reco=1).save()
models.ExposureData(
exposure_model=model, taxonomy="aa/aatc-D/LR",
asset_ref="ASSET_2", stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()), reco=1).save()
site = shapes.Site(2.0, 2.0)
# just one asset at location
models.ExposureData(
exposure_model=model, taxonomy="aa/aatc-D/LR",
asset_ref="ASSET_3", stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()), reco=1).save()
def _store_em(self):
[ism] = models.inputs4job(self.job.id, input_type="exposure")
em = models.ExposureModel(owner=ism.owner,
input=ism,
name="AAA",
category="single_asset",
reco_type="aggregated",
reco_unit="USD",
stco_type="aggregated",
stco_unit="USD")
em.save()
models.ExposureData(exposure_model=em,
taxonomy="RC",
asset_ref="A",
number_of_units=100,
stco=1,
site=geos.GEOSGeometry(self.site.point.to_wkt()),
reco=1).save()
models.ExposureData(exposure_model=em,
taxonomy="RM",
asset_ref="B",
number_of_units=40,
stco=1,
site=geos.GEOSGeometry(self.site.point.to_wkt()),
reco=1).save()
return em
def test_model_content_unknown_content_type(self):
test_file = helpers.touch()
params = dict(GMPE_LOGIC_TREE_FILE=test_file)
engine._insert_input_files(params, self.job, True)
[glt] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertEqual('unknown', glt.model_content.content_type)
def store_exposure_assets(self):
"""Load exposure assets and write them to database."""
[emdl] = models.inputs4job(self.job_ctxt.job_id, "exposure")
path = os.path.join(self.job_ctxt.base_path, emdl.path)
exposure_parser = exposure.ExposureModelFile(path)
writer = ExposureDBWriter(emdl)
writer.serialize(exposure_parser)
def _load_exposure_model(cls, job_id):
"""Load and cache the exposure model."""
if cls._em_inputs is None or cls._em_job_id != job_id:
# This query obtains the exposure model input rows and needs to be
# made only once in the course of a risk calculation.
cls._em_inputs = models.inputs4job(job_id, "exposure")
cls._em_job_id = job_id
def _load_exposure_model(cls, job_id):
"""Load and cache the exposure model."""
if cls._em_inputs is None or cls._em_job_id != job_id:
# This query obtains the exposure model input rows and needs to be
# made only once in the course of a risk calculation.
cls._em_inputs = models.inputs4job(job_id, "exposure")
cls._em_job_id = job_id
def test_model_content_unknown_content_type(self):
test_file = helpers.touch()
params = dict(GMPE_LOGIC_TREE_FILE=test_file)
engine._insert_input_files(params, self.job, True)
[glt] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertEqual('unknown', glt.model_content.content_type)
def test_inputs4job_with_single_input(self):
# The single input is returned.
inp = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="exposure",
size=self.sizes.next())
inp.save()
models.Input2job(oq_job=self.job, input=inp).save()
self.assertEqual([inp], models.inputs4job(self.job.id))
def test_inputs4job_with_wrong_path(self):
# No input is returned.
inp = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="exposure",
size=self.sizes.next())
inp.save()
models.Input2job(oq_job=self.job, input=inp).save()
self.assertEqual([], models.inputs4job(self.job.id, path="xyz"))
def _fm(oq_job):
"""
Return the fragility model related to the current computation.
"""
[ism] = inputs4job(oq_job.id, input_type="fragility")
[fm] = FragilityModel.objects.filter(input=ism, owner=oq_job.owner)
return fm
def _fm(oq_job):
"""
Return the fragility model related to the current computation.
"""
[ism] = inputs4job(oq_job.id, input_type="fragility")
[fm] = FragilityModel.objects.filter(input=ism, owner=oq_job.owner)
return fm
def test_model_content_single_file(self):
# The contents of input files (such as logic trees, exposure models,
# etc.) should be saved to the uiapi.model_content table.
slt_path = os.path.join(self.PARAMS['BASE_PATH'], self.SLT)
expected_content = open(slt_path, 'r').read()
engine._insert_input_files(self.PARAMS, self.job, True)
[slt] = models.inputs4job(self.job.id, input_type="lt_source")
self.assertEqual('xml', slt.model_content.content_type)
self.assertEqual(expected_content, slt.model_content.raw_content)
def setUp(self):
path = os.path.join(helpers.SCHEMA_EXAMPLES_DIR, "LCB-exposure.yaml")
inputs = [("exposure", path)]
self.job = self.setup_classic_job(inputs=inputs)
[input] = models.inputs4job(self.job.id,
input_type="exposure",
path=path)
owner = models.OqUser.objects.get(user_name="openquake")
emdl = input.model()
if not emdl:
emdl = models.ExposureModel(owner=owner,
input=input,
description="LCB exposure model",
category="LCB cars",
stco_unit="peanuts",
stco_type="aggregated")
emdl.save()
asset_data = [
(Site(-118.077721, 33.852034), {
u'stco': 5.07,
u'asset_ref': u'a5625',
u'taxonomy': u'HAZUS_RM1L_LC'
}),
(Site(-118.077721, 33.852034), {
u'stco': 5.63,
u'asset_ref': u'a5629',
u'taxonomy': u'HAZUS_URML_LC'
}),
(Site(-118.077721, 33.852034), {
u'stco': 11.26,
u'asset_ref': u'a5630',
u'taxonomy': u'HAZUS_URML_LS'
}),
(Site(-118.077721, 33.852034), {
u'stco': 5.5,
u'asset_ref': u'a5636',
u'taxonomy': u'HAZUS_C3L_MC'
}),
]
for idx, (site, adata) in enumerate(asset_data):
location = GEOSGeometry(site.point.to_wkt())
asset = models.ExposureData(exposure_model=emdl,
site=location,
**adata)
asset.save()
RISK_LOSS_CURVE_DATA[idx][1][1] = asset
output_path = self.generate_output_path(self.job)
self.display_name = os.path.basename(output_path)
self.writer = LossCurveDBWriter(output_path, self.job.id)
self.reader = LossCurveDBReader()
def store_exposure_assets(self):
"""Load exposure assets and write them to database."""
[emi] = models.inputs4job(self.job_ctxt.job_id, "exposure")
if emi.exposuremodel_set.all().count() > 0:
return
path = os.path.join(self.job_ctxt.base_path, emi.path)
exposure_parser = exposure.ExposureModelFile(path)
writer = ExposureDBWriter(emi)
writer.serialize(exposure_parser)
return emi.model()
def setUp(self):
path = os.path.join(helpers.SCHEMA_EXAMPLES_DIR, TEST_FILE)
inputs = [("exposure", path)]
self.job = self.setup_classic_job(inputs=inputs)
[input] = models.inputs4job(self.job.id, input_type="exposure",
path=path)
writer = ExposureDBWriter(input)
exposure_parser = exposure.ExposureModelFile(path)
writer.serialize(exposure_parser)
self.model = writer.model
self.epsilon_provider = general.EpsilonProvider(dict())
def setUp(self):
path = os.path.join(helpers.SCHEMA_EXAMPLES_DIR, "LMB-exposure.yaml")
inputs = [("exposure", path)]
self.job = self.setup_classic_job(inputs=inputs)
[input] = models.inputs4job(self.job.id,
input_type="exposure",
path=path)
owner = models.OqUser.objects.get(user_name="openquake")
emdl = input.model()
if not emdl:
emdl = models.ExposureModel(owner=owner,
input=input,
description="LMB exposure model",
category="LMB yachts",
stco_unit="oranges",
stco_type="aggregated")
emdl.save()
asset_data = [
("asset_a_1", SITE_A, {
u'stco': 5.07,
u'asset_ref': u'a1711',
u'taxonomy': u'HAZUS_RM1L_LC'
}),
("asset_a_2", SITE_A, {
u'stco': 5.63,
u'asset_ref': u'a1712',
u'taxonomy': u'HAZUS_URML_LC'
}),
("asset_b_1", SITE_B, {
u'stco': 5.5,
u'asset_ref': u'a1713',
u'taxonomy': u'HAZUS_C3L_MC'
}),
]
for idx, (name, site, adata) in enumerate(asset_data):
location = GEOSGeometry(site.point.to_wkt())
asset = models.ExposureData(exposure_model=emdl,
site=location,
**adata)
asset.save()
setattr(self, name, asset)
SAMPLE_NONSCENARIO_LOSS_MAP_DATA[1][1][0][1] = self.asset_a_1
SAMPLE_NONSCENARIO_LOSS_MAP_DATA[1][1][1][1] = self.asset_a_2
SAMPLE_NONSCENARIO_LOSS_MAP_DATA[2][1][0][1] = self.asset_b_1
output_path = self.generate_output_path(self.job)
self.display_name = os.path.basename(output_path)
self.writer = LossMapDBWriter(output_path, self.job.id)
self.reader = LossMapDBReader()
def test_model_content_single_file(self):
# The contents of input files (such as logic trees, exposure models,
# etc.) should be saved to the uiapi.model_content table.
expected_content = open(self.SLT, 'r').read()
params = dict(SOURCE_MODEL_LOGIC_TREE_FILE=self.SLT)
engine._insert_input_files(params, self.job, True)
[slt] = models.inputs4job(self.job.id, input_type="lt_source")
self.assertEqual('xml', slt.model_content.content_type)
self.assertEqual(expected_content, slt.model_content.raw_content)
def test_model_content_single_file(self):
# The contents of input files (such as logic trees, exposure models,
# etc.) should be saved to the uiapi.model_content table.
expected_content = open(self.SLT, 'r').read()
params = dict(SOURCE_MODEL_LOGIC_TREE_FILE=self.SLT)
engine._insert_input_files(params, self.job, True)
[slt] = models.inputs4job(self.job.id, input_type="lt_source")
self.assertEqual('xml', slt.model_content.content_type)
self.assertEqual(expected_content, slt.model_content.raw_content)
def test_inputs4job_with_correct_path(self):
# The exposure inputs are returned.
inp1 = models.Input(owner=self.job.owner, path=self.paths.next(),
input_type="exposure", size=self.sizes.next())
inp1.save()
models.Input2job(oq_job=self.job, input=inp1).save()
path = self.paths.next()
inp2 = models.Input(owner=self.job.owner, path=path,
input_type="rupture", size=self.sizes.next())
inp2.save()
models.Input2job(oq_job=self.job, input=inp2).save()
self.assertEqual([inp2], models.inputs4job(self.job.id, path=path))
def setUp(self):
self.job_ctxt = helpers.job_from_file(os.path.join(helpers.DATA_DIR,
'config.gem'))
[input] = models.inputs4job(self.job_ctxt.job_id,
input_type="exposure")
owner = models.OqUser.objects.get(user_name="openquake")
emdl = input.model()
if not emdl:
emdl = models.ExposureModel(
owner=owner, input=input, description="RCT exposure model",
category="RCT villas", stco_unit="roofs",
stco_type="aggregated")
emdl.save()
asset_data = [
((0, 0), shapes.Site(10.0, 10.0),
{u'stco': 5.07, u'asset_ref': u'a5625',
u'taxonomy': u'rctc-ad-83'}),
((0, 1), shapes.Site(10.1, 10.0),
{u'stco': 5.63, u'asset_ref': u'a5629',
u'taxonomy': u'rctc-ad-83'}),
((1, 0), shapes.Site(10.0, 10.1),
{u'stco': 11.26, u'asset_ref': u'a5630',
u'taxonomy': u'rctc-ad-83'}),
((1, 1), shapes.Site(10.1, 10.1),
{u'stco': 5.5, u'asset_ref': u'a5636',
u'taxonomy': u'rctc-ad-83'}),
]
assets = emdl.exposuredata_set.filter(taxonomy="rctc-ad-83"). \
order_by("id")
for idx, (gcoo, site, adata) in enumerate(asset_data):
if not assets:
location = geos.GEOSGeometry(site.point.to_wkt())
asset = models.ExposureData(exposure_model=emdl, site=location,
**adata)
asset.save()
else:
asset = assets[idx]
GRID_ASSETS[gcoo] = asset
self.grid = shapes.Grid(shapes.Region.from_coordinates(
[(10.0, 10.0), (10.0, 10.1), (10.1, 10.1), (10.1, 10.0)]), 0.1)
# this is the expected output of grid_assets_iterator and an input of
# asset_losses_per_site
self.grid_assets = [
(shapes.GridPoint(self.grid, 0, 0), GRID_ASSETS[(0, 0)]),
(shapes.GridPoint(self.grid, 1, 0), GRID_ASSETS[(0, 1)]),
(shapes.GridPoint(self.grid, 0, 1), GRID_ASSETS[(1, 0)]),
(shapes.GridPoint(self.grid, 1, 1), GRID_ASSETS[(1, 1)])]
def setUp(self):
path = os.path.join(helpers.SCHEMA_EXAMPLES_DIR, TEST_FILE)
inputs = [("exposure", path)]
self.job = self.setup_classic_job(inputs=inputs)
[input] = models.inputs4job(self.job.id,
input_type="exposure",
path=path)
writer = ExposureDBWriter(input)
exposure_parser = exposure.ExposureModelFile(path)
writer.serialize(exposure_parser)
self.model = writer.model
self.epsilon_provider = general.EpsilonProvider(
dict(EPSILON_RANDOM_SEED=37))
def store_fragility_model(self):
"""Load fragility model and write it to database."""
new_models = []
fmis = models.inputs4job(self.job_ctxt.job_id, "fragility")
for fmi in fmis:
if fmi.fragilitymodel_set.all().count() > 0:
continue
path = os.path.join(self.job_ctxt.base_path, fmi.path)
parser = fragility.FragilityModelParser(path)
writer = FragilityDBWriter(fmi, parser)
writer.serialize()
new_models.append(writer.model)
return new_models if new_models else None
def store_fragility_model(self):
"""Load fragility model and write it to database."""
new_models = []
fmis = models.inputs4job(self.job_ctxt.job_id, "fragility")
for fmi in fmis:
if fmi.fragilitymodel_set.all().count() > 0:
continue
path = os.path.join(self.job_ctxt.base_path, fmi.path)
parser = fragility.FragilityModelParser(path)
writer = FragilityDBWriter(fmi, parser)
writer.serialize()
new_models.append(writer.model)
return new_models if new_models else None
def test_model_content_detect_content_type(self):
# Test detection of the content type (using the file extension).
test_file = helpers.touch(suffix=".html")
# We use the gmpe logic tree as our test target because there is no
# parsing required in the function under test. Thus, we can put
# whatever test garbage we want in the file, or just use an empty file
# (which is the case here).
params = dict(GMPE_LOGIC_TREE_FILE=test_file)
engine._insert_input_files(params, self.job, True)
[glt] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertEqual('html', glt.model_content.content_type)
def test_model_content_detect_content_type(self):
# Test detection of the content type (using the file extension).
test_file = helpers.touch(suffix=".html")
# We use the gmpe logic tree as our test target because there is no
# parsing required in the function under test. Thus, we can put
# whatever test garbage we want in the file, or just use an empty file
# (which is the case here).
params = dict(GMPE_LOGIC_TREE_FILE=test_file)
engine._insert_input_files(params, self.job, True)
[glt] = models.inputs4job(self.job.id, input_type="lt_gmpe")
self.assertEqual('html', glt.model_content.content_type)
def test_compute_bcr_in_the_classical_psha_calculator(self):
self._compute_risk_classical_psha_setup()
helpers.delete_profile(self.job)
bcr_config = helpers.demo_file('benefit_cost_ratio/config.gem')
job_profile, params, sections = engine.import_job_profile(
bcr_config, self.job)
# We need to adjust a few of the parameters for this test:
job_profile.imls = [
0.005, 0.007, 0.0098, 0.0137, 0.0192, 0.0269, 0.0376, 0.0527,
0.0738, 0.103, 0.145, 0.203, 0.284, 0.397, 0.556, 0.778]
params['ASSET_LIFE_EXPECTANCY'] = '50'
job_profile.asset_life_expectancy = 50
params['REGION_VERTEX'] = '0.0, 0.0, 0.0, 2.0, 2.0, 2.0, 2.0, 0.0'
job_profile.region = GEOSGeometry(shapes.polygon_ewkt_from_coords(
params['REGION_VERTEX']))
job_profile.save()
job_ctxt = engine.JobContext(
params, self.job_id, sections=sections, oq_job_profile=job_profile)
calculator = classical_core.ClassicalRiskCalculator(job_ctxt)
[input] = models.inputs4job(self.job.id, input_type="exposure")
emdl = input.model()
if not emdl:
emdl = models.ExposureModel(
owner=self.job.owner, input=input,
description="c-psha test exposure model",
category="c-psha power plants", stco_unit="watt",
stco_type="aggregated", reco_unit="joule",
reco_type="aggregated")
emdl.save()
assets = emdl.exposuredata_set.filter(asset_ref="rubcr")
if not assets:
asset = models.ExposureData(exposure_model=emdl, taxonomy="ID",
asset_ref="rubcr", stco=1, reco=123.45,
site=GEOSGeometry("POINT(1.0 1.0)"))
asset.save()
Block.from_kvs(self.job_id, self.block_id)
calculator.compute_risk(self.block_id)
result_key = kvs.tokens.bcr_block_key(self.job_id, self.block_id)
res = kvs.get_value_json_decoded(result_key)
expected_result = {'bcr': 0.0, 'eal_original': 0.003032,
'eal_retrofitted': 0.003032}
helpers.assertDeepAlmostEqual(
self, res, [[[1, 1], [[expected_result, "rubcr"]]]])
def setUpClass(cls):
path = os.path.join(helpers.SCHEMA_EXAMPLES_DIR, "SEB-exposure.yaml")
inputs = [("exposure", path)]
cls.job = cls.setup_classic_job(inputs=inputs)
[input] = models.inputs4job(cls.job.id, input_type="exposure",
path=path)
owner = models.OqUser.objects.get(user_name="openquake")
cls.emdl = input.model()
if not cls.emdl:
cls.emdl = models.ExposureModel(
owner=owner, input=input, description="SEB exposure model",
category="SEB factory buildings", stco_unit="screws",
stco_type="aggregated")
cls.emdl.save()
def setUpClass(cls):
path = os.path.join(helpers.SCHEMA_EXAMPLES_DIR, "SEB-exposure.yaml")
inputs = [("exposure", path)]
cls.job = cls.setup_classic_job(inputs=inputs)
[input] = models.inputs4job(cls.job.id,
input_type="exposure",
path=path)
owner = models.OqUser.objects.get(user_name="openquake")
cls.emdl = input.model()
if not cls.emdl:
cls.emdl = models.ExposureModel(owner=owner,
input=input,
description="SEB exposure model",
category="SEB factory buildings",
stco_unit="screws",
stco_type="aggregated")
cls.emdl.save()
def test_inputs4job_with_correct_input_type(self):
# The exposure inputs are returned.
inp1 = models.Input(owner=self.job.owner, path=self.paths.next(),
input_type="exposure", size=self.sizes.next())
inp1.save()
models.Input2job(oq_job=self.job, input=inp1).save()
inp2 = models.Input(owner=self.job.owner, path=self.paths.next(),
input_type="rupture", size=self.sizes.next())
inp2.save()
models.Input2job(oq_job=self.job, input=inp2).save()
inp3 = models.Input(owner=self.job.owner, path=self.paths.next(),
input_type="exposure", size=self.sizes.next())
inp3.save()
models.Input2job(oq_job=self.job, input=inp3).save()
actual = sorted(models.inputs4job(self.job.id, input_type="exposure"),
key=lambda input: input.id)
self.assertEqual([inp1, inp3], actual)
def read_sites_from_exposure(job_ctxt):
"""
Given a :class:`JobContext` object, get all of the sites in the exposure
model which are contained by the region of interest (defined in the
`JobContext`).
It is assumed that exposure model is already loaded into the database.
:param job_ctxt:
:class:`JobContext` instance.
:returns:
`list` of :class:`openquake.shapes.Site` objects, with no duplicates
"""
em_inputs = models.inputs4job(job_ctxt.job_id, input_type="exposure")
exp_points = models.ExposureData.objects.filter(
exposure_model__input__id__in=[em.id for em in em_inputs],
site__contained=job_ctxt.oq_job_profile.region).values(
'site').distinct()
return [shapes.Site(p['site'].x, p['site'].y) for p in exp_points]
def setUpClass(cls):
cls.job = engine.prepare_job()
jp, _, _ = engine.import_job_profile(RISK_DEMO_CONFIG_FILE, cls.job)
calc_proxy = helpers.create_job({},
job_id=cls.job.id,
oq_job_profile=jp,
oq_job=cls.job)
# storing the basic exposure model
ClassicalRiskCalculator(calc_proxy).store_exposure_assets()
[input] = models.inputs4job(cls.job.id, input_type="exposure")
model = input.model()
assets = model.exposuredata_set.filter(taxonomy="aa/aatc-D/LR")
if not assets:
# This model did not exist in the database before.
site = shapes.Site(1.0, 2.0)
# more assets at same location
models.ExposureData(exposure_model=model,
taxonomy="aa/aatc-D/LR",
asset_ref="ASSET_1",
stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()),
reco=1).save()
models.ExposureData(exposure_model=model,
taxonomy="aa/aatc-D/LR",
asset_ref="ASSET_2",
stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()),
reco=1).save()
site = shapes.Site(2.0, 2.0)
# just one asset at location
models.ExposureData(exposure_model=model,
taxonomy="aa/aatc-D/LR",
asset_ref="ASSET_3",
stco=1,
site=geos.GEOSGeometry(site.point.to_wkt()),
reco=1).save()
def test_inputs4job_with_correct_input_type(self):
# The exposure inputs are returned.
inp1 = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="exposure",
size=self.sizes.next())
inp1.save()
models.Input2job(oq_job=self.job, input=inp1).save()
inp2 = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="rupture",
size=self.sizes.next())
inp2.save()
models.Input2job(oq_job=self.job, input=inp2).save()
inp3 = models.Input(owner=self.job.owner,
path=self.paths.next(),
input_type="exposure",
size=self.sizes.next())
inp3.save()
models.Input2job(oq_job=self.job, input=inp3).save()
self.assertEqual([inp1, inp3],
models.inputs4job(self.job.id, input_type="exposure"))
def get_site_model(job_id):
"""Get the site model :class:`~openquake.db.models.Input` record for the
given job id.
:param int job_id:
ID of a job.
:returns:
The site model :class:`~openquake.db.models.Input` record for this job.
:raises:
:exc:`RuntimeError` if the job has more than 1 site model.
"""
site_model = models.inputs4job(job_id, input_type='site_model')
if len(site_model) == 0:
return None
elif len(site_model) > 1:
# Multiple site models for 1 job are not allowed.
raise RuntimeError("Only 1 site model per job is allowed, found %s."
% len(site_model))
# There's only one site model.
return site_model[0]
def teardown_job(cls, job, filesystem_only=True):
"""
Tear down the file system (and potentially db) artefacts for the
given job.
:param job: a :py:class:`db.models.OqJob` instance
:param bool filesystem_only: if set the oq_job/oq_param/upload/
input database records will be left intact. This saves time and the
test db will be dropped/recreated prior to the next db test suite
run anyway.
"""
DbTestCase.teardown_inputs(models.inputs4job(job.id),
filesystem_only=filesystem_only)
if filesystem_only:
return
job.delete()
try:
oqjp = models.profile4job(job.id)
oqjp.delete()
except ValueError:
# no job profile for this job
pass
def test_initialize_stores_site_model(self):
job_ctxt = helpers.prepare_job_context(
helpers.demo_file(
'simple_fault_demo_hazard/config_with_site_model.gem'))
calc = general.BaseHazardCalculator(job_ctxt)
[site_model_input] = models.inputs4job(
job_ctxt.oq_job.id, input_type='site_model')
site_model_nodes = models.SiteModel.objects.filter(
input=site_model_input)
# Test precondition: The site_model table shouldn't be populated yet.
self.assertEqual(0, len(site_model_nodes))
calc.initialize()
# Now it should be populated.
site_model_nodes = models.SiteModel.objects.filter(
input=site_model_input)
# It would be overkill to test the contents; just check that the number
# of records is correct.
self.assertEqual(2601, len(site_model_nodes))
