def test_find(self):
rp = resource_provider.ResourceProvider(uuid=uuids.rp_uuid)
inv_list = resource_provider.InventoryList(objects=[
resource_provider.Inventory(
resource_provider=rp,
resource_class=fields.ResourceClass.VCPU,
total=24),
resource_provider.Inventory(
resource_provider=rp,
resource_class=fields.ResourceClass.MEMORY_MB,
total=10240),
])
found = inv_list.find(fields.ResourceClass.MEMORY_MB)
self.assertIsNotNone(found)
self.assertEqual(10240, found.total)
found = inv_list.find(fields.ResourceClass.VCPU)
self.assertIsNotNone(found)
self.assertEqual(24, found.total)
found = inv_list.find(fields.ResourceClass.DISK_GB)
self.assertIsNone(found)
# Try an integer resource class identifier...
self.assertRaises(ValueError, inv_list.find, VCPU_ID)
# Use an invalid string...
self.assertIsNone(inv_list.find('HOUSE'))
def start_fixture(self):
super(NonSharedStorageFixture, self).start_fixture()
self.context = context.get_admin_context()
cn1_uuid = uuidutils.generate_uuid()
cn2_uuid = uuidutils.generate_uuid()
aggA_uuid = uuidutils.generate_uuid()
aggB_uuid = uuidutils.generate_uuid()
aggC_uuid = uuidutils.generate_uuid()
os.environ['CN1_UUID'] = cn1_uuid
os.environ['CN2_UUID'] = cn2_uuid
os.environ['AGGA_UUID'] = aggA_uuid
os.environ['AGGB_UUID'] = aggB_uuid
os.environ['AGGC_UUID'] = aggC_uuid
cn1 = rp_obj.ResourceProvider(self.context, name='cn1', uuid=cn1_uuid)
cn1.create()
cn2 = rp_obj.ResourceProvider(self.context, name='cn2', uuid=cn2_uuid)
cn2.create()
# Populate compute node inventory for VCPU and RAM
for cn in (cn1, cn2):
vcpu_inv = rp_obj.Inventory(self.context,
resource_provider=cn,
resource_class='VCPU',
total=24,
reserved=0,
max_unit=24,
min_unit=1,
step_size=1,
allocation_ratio=16.0)
vcpu_inv.obj_set_defaults()
ram_inv = rp_obj.Inventory(self.context,
resource_provider=cn,
resource_class='MEMORY_MB',
total=128 * 1024,
reserved=0,
max_unit=128 * 1024,
min_unit=256,
step_size=256,
allocation_ratio=1.5)
ram_inv.obj_set_defaults()
disk_inv = rp_obj.Inventory(self.context,
resource_provider=cn,
resource_class='DISK_GB',
total=2000,
reserved=100,
max_unit=2000,
min_unit=10,
step_size=10,
allocation_ratio=1.0)
disk_inv.obj_set_defaults()
inv_list = rp_obj.InventoryList(
objects=[vcpu_inv, ram_inv, disk_inv])
cn.set_inventory(inv_list)
def add_inventory(rp, rc, total, **kwargs):
kwargs.setdefault('max_unit', total)
inv = rp_obj.Inventory(rp._context, resource_provider=rp,
resource_class=rc, total=total, **kwargs)
inv.obj_set_defaults()
rp.add_inventory(inv)
return inv
def test_create_with_id_fails(self):
rp = resource_provider.ResourceProvider(context=self.context,
uuid=_RESOURCE_PROVIDER_UUID,
name=_RESOURCE_PROVIDER_NAME)
rp.create()
inv = resource_provider.Inventory(context=self.context,
resource_provider=rp,
resource_class=_RESOURCE_CLASS_NAME,
total=16,
reserved=2,
min_unit=1,
max_unit=8,
step_size=1,
allocation_ratio=1.0)
inv_list = resource_provider.InventoryList(context=self.context,
objects=[inv])
rp.set_inventory(inv_list)
obj = resource_provider.Allocation(context=self.context,
id=99,
resource_provider=rp,
resource_class=_RESOURCE_CLASS_NAME,
consumer_id=uuids.fake_instance,
used=8)
alloc_list = resource_provider.AllocationList(self.context,
objects=[obj])
self.assertRaises(exception.ObjectActionError, alloc_list.create_all)
def test_create(self, mock_ensure_cache):
rp = resource_provider.ResourceProvider(context=self.context,
uuid=_RESOURCE_PROVIDER_UUID,
name=_RESOURCE_PROVIDER_NAME)
rp.create()
inv = resource_provider.Inventory(context=self.context,
resource_provider=rp,
resource_class=_RESOURCE_CLASS_NAME,
total=16,
reserved=2,
min_unit=1,
max_unit=8,
step_size=1,
allocation_ratio=1.0)
inv_list = resource_provider.InventoryList(context=self.context,
objects=[inv])
rp.set_inventory(inv_list)
obj = resource_provider.Allocation(context=self.context,
resource_provider=rp,
resource_class=_RESOURCE_CLASS_NAME,
consumer_id=uuids.fake_instance,
used=8)
alloc_list = resource_provider.AllocationList(self.context,
objects=[obj])
alloc_list.create_all()
rp_al = resource_provider.AllocationList
saved_allocations = rp_al.get_all_by_resource_provider(
self.context, rp)
self.assertEqual(1, len(saved_allocations))
self.assertEqual(obj.used, saved_allocations[0].used)
def _create_resource_provider(self, inventory):
"""Helper method to create a resource provider with inventory"""
ctxt = context.get_admin_context()
rp_uuid = uuidutils.generate_uuid()
rp = rp_obj.ResourceProvider(context=ctxt, name=rp_uuid, uuid=rp_uuid)
rp.create()
inv = rp_obj.Inventory(context=ctxt, resource_provider=rp, **inventory)
inv_list = rp_obj.InventoryList(objects=[inv])
rp.set_inventory(inv_list)
return rp
def _make_allocation(self, inv_dict, alloc_dict):
rp = self._create_provider('allocation_resource_provider')
disk_inv = rp_obj.Inventory(context=self.ctx,
resource_provider=rp,
**inv_dict)
inv_list = rp_obj.InventoryList(objects=[disk_inv])
rp.set_inventory(inv_list)
alloc = rp_obj.Allocation(self.ctx, resource_provider=rp, **alloc_dict)
alloc_list = rp_obj.AllocationList(self.ctx, objects=[alloc])
alloc_list.create_all()
return rp, alloc
def test_set_defaults(self):
rp = resource_provider.ResourceProvider(id=_RESOURCE_PROVIDER_ID,
uuid=_RESOURCE_PROVIDER_UUID)
kwargs = dict(resource_provider=rp,
resource_class=_RESOURCE_CLASS_NAME,
total=16)
inv = resource_provider.Inventory(self.context, **kwargs)
inv.obj_set_defaults()
self.assertEqual(0, inv.reserved)
self.assertEqual(1, inv.min_unit)
self.assertEqual(1, inv.max_unit)
self.assertEqual(1, inv.step_size)
self.assertEqual(1.0, inv.allocation_ratio)
def _make_allocation(self, inv_dict, alloc_dict):
rp = self._create_provider('allocation_resource_provider')
disk_inv = rp_obj.Inventory(context=self.ctx,
resource_provider=rp, **inv_dict)
inv_list = rp_obj.InventoryList(objects=[disk_inv])
rp.set_inventory(inv_list)
consumer_id = alloc_dict['consumer_id']
consumer = ensure_consumer(
self.ctx, self.user_obj, self.project_obj, consumer_id)
alloc = rp_obj.Allocation(self.ctx, resource_provider=rp,
consumer=consumer, **alloc_dict)
alloc_list = rp_obj.AllocationList(self.ctx, objects=[alloc])
alloc_list.replace_all()
return rp, alloc
def test_capacity(self):
rp = resource_provider.ResourceProvider(id=_RESOURCE_PROVIDER_ID,
uuid=_RESOURCE_PROVIDER_UUID)
kwargs = dict(resource_provider=rp,
resource_class=_RESOURCE_CLASS_NAME,
total=16,
reserved=16)
inv = resource_provider.Inventory(self.context, **kwargs)
inv.obj_set_defaults()
self.assertEqual(0, inv.capacity)
inv.reserved = 15
self.assertEqual(1, inv.capacity)
inv.allocation_ratio = 2.0
self.assertEqual(2, inv.capacity)
def make_inventory_object(resource_provider, resource_class, **data):
"""Single place to catch malformed Inventories."""
# TODO(cdent): Some of the validation checks that are done here
# could be done via JSONschema (using, for example, "minimum":
# 0) for non-negative integers. It's not clear if that is
# duplication or decoupling so leaving it as this for now.
try:
inventory = rp_obj.Inventory(
resource_provider=resource_provider,
resource_class=resource_class, **data)
except (ValueError, TypeError) as exc:
raise webob.exc.HTTPBadRequest(
_('Bad inventory %(class)s for resource provider '
'%(rp_uuid)s: %(error)s') % {'class': resource_class,
'rp_uuid': resource_provider.uuid,
'error': exc})
return inventory
def _make_allocation(self, inv_dict, alloc_dict):
rp = self._create_provider('allocation_resource_provider')
disk_inv = rp_obj.Inventory(context=self.ctx,
resource_provider=rp, **inv_dict)
inv_list = rp_obj.InventoryList(objects=[disk_inv])
rp.set_inventory(inv_list)
consumer_id = alloc_dict['consumer_id']
try:
c = consumer_obj.Consumer.get_by_uuid(self.ctx, consumer_id)
except exception.NotFound:
c = consumer_obj.Consumer(
self.ctx, uuid=consumer_id, user=self.user_obj,
project=self.project_obj)
c.create()
alloc = rp_obj.Allocation(self.ctx, resource_provider=rp,
consumer=c, **alloc_dict)
alloc_list = rp_obj.AllocationList(self.ctx, objects=[alloc])
alloc_list.replace_all()
return rp, alloc
def start_fixture(self):
super(AllocationFixture, self).start_fixture()
self.context = context.get_admin_context()
# For use creating and querying allocations/usages
os.environ['ALT_USER_ID'] = uuidutils.generate_uuid()
project_id = os.environ['PROJECT_ID']
user_id = os.environ['USER_ID']
alt_user_id = os.environ['ALT_USER_ID']
user = user_obj.User(self.context, external_id=user_id)
user.create()
alt_user = user_obj.User(self.context, external_id=alt_user_id)
alt_user.create()
project = project_obj.Project(self.context, external_id=project_id)
project.create()
# Stealing from the super
rp_name = os.environ['RP_NAME']
rp_uuid = os.environ['RP_UUID']
rp = rp_obj.ResourceProvider(self.context, name=rp_name, uuid=rp_uuid)
rp.create()
# Create a first consumer for the DISK_GB
consumer_id = uuidutils.generate_uuid()
consumer = consumer_obj.Consumer(self.context,
uuid=consumer_id,
user=user,
project=project)
consumer.create()
# Create some DISK_GB inventory and allocations.
inventory = rp_obj.Inventory(self.context,
resource_provider=rp,
resource_class='DISK_GB',
total=2048,
step_size=10,
min_unit=10,
max_unit=600)
inventory.obj_set_defaults()
rp.add_inventory(inventory)
alloc1 = rp_obj.Allocation(self.context,
resource_provider=rp,
resource_class='DISK_GB',
consumer=consumer,
used=500)
alloc2 = rp_obj.Allocation(self.context,
resource_provider=rp,
resource_class='DISK_GB',
consumer=consumer,
used=500)
alloc_list = rp_obj.AllocationList(self.context,
objects=[alloc1, alloc2])
alloc_list.create_all()
# Create a second consumer for the VCPU
consumer_id = uuidutils.generate_uuid()
consumer = consumer_obj.Consumer(self.context,
uuid=consumer_id,
user=user,
project=project)
consumer.create()
# This consumer is referenced from the gabbits
os.environ['CONSUMER_ID'] = consumer_id
# Create some VCPU inventory and allocations.
inventory = rp_obj.Inventory(self.context,
resource_provider=rp,
resource_class='VCPU',
total=10,
max_unit=4)
inventory.obj_set_defaults()
rp.add_inventory(inventory)
alloc1 = rp_obj.Allocation(self.context,
resource_provider=rp,
resource_class='VCPU',
consumer=consumer,
used=2)
alloc2 = rp_obj.Allocation(self.context,
resource_provider=rp,
resource_class='VCPU',
consumer=consumer,
used=4)
alloc_list = rp_obj.AllocationList(self.context,
objects=[alloc1, alloc2])
alloc_list.create_all()
# Create a consumer object for a different user
alt_consumer_id = uuidutils.generate_uuid()
alt_consumer = consumer_obj.Consumer(self.context,
uuid=alt_consumer_id,
user=alt_user,
project=project)
alt_consumer.create()
os.environ['ALT_CONSUMER_ID'] = alt_consumer_id
# Create a couple of allocations for a different user.
alloc1 = rp_obj.Allocation(self.context,
resource_provider=rp,
resource_class='DISK_GB',
consumer=alt_consumer,
used=20)
alloc2 = rp_obj.Allocation(self.context,
resource_provider=rp,
resource_class='VCPU',
consumer=alt_consumer,
used=1)
alloc_list = rp_obj.AllocationList(self.context,
objects=[alloc1, alloc2])
alloc_list.create_all()
# The ALT_RP_XXX variables are for a resource provider that has
# not been created in the Allocation fixture
os.environ['ALT_RP_UUID'] = uuidutils.generate_uuid()
os.environ['ALT_RP_NAME'] = uuidutils.generate_uuid()
def test_reshape_concurrent_inventory_update(self):
"""Valid failure scenario for reshape(). We test a situation where the
virt driver has constructed it's "after inventories and allocations"
and sent those to the POST /reshape endpoint. The reshape POST handler
does a quick check of the resource provider generations sent in the
payload and they all check out.
However, right before the call to resource_provider.reshape(), another
thread legitimately changes the inventory of one of the providers
involved in the reshape transaction. We should get a
ConcurrentUpdateDetected in this case.
"""
# First create our consumers
i1_uuid = uuids.instance1
i1_consumer = consumer_obj.Consumer(self.ctx,
uuid=i1_uuid,
user=self.user_obj,
project=self.project_obj)
i1_consumer.create()
# then all our original providers
cn1 = self._create_provider('cn1')
tb.add_inventory(cn1, 'VCPU', 16)
tb.add_inventory(cn1, 'MEMORY_MB', 32768)
tb.add_inventory(cn1, 'DISK_GB', 1000)
# Allocate an instance on our compute node
allocs = [
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='VCPU',
consumer=i1_consumer,
used=2),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
consumer=i1_consumer,
used=1024),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='DISK_GB',
consumer=i1_consumer,
used=100),
]
alloc_list = rp_obj.AllocationList(self.ctx, objects=allocs)
alloc_list.replace_all()
# Before we issue the actual reshape() call, we need to first create
# the child providers and sharing storage provider. These are actions
# that the virt driver or external agent is responsible for performing
# *before* attempting any reshape activity.
cn1_numa0 = self._create_provider('cn1_numa0', parent=cn1.uuid)
cn1_numa1 = self._create_provider('cn1_numa1', parent=cn1.uuid)
ss = self._create_provider('ss')
# OK, now emulate the call to POST /reshaper that will be triggered by
# a virt driver wanting to replace the world and change its modeling
# from a single provider to a nested provider tree along with a sharing
# storage provider.
after_inventories = {
# cn1 keeps the RAM only
cn1:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
total=32768,
reserved=0,
max_unit=32768,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
# each NUMA node gets half of the CPUs
cn1_numa0:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=cn1_numa0,
resource_class='VCPU',
total=8,
reserved=0,
max_unit=8,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
cn1_numa1:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=cn1_numa1,
resource_class='VCPU',
total=8,
reserved=0,
max_unit=8,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
# The sharing provider gets a bunch of disk
ss:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(self.ctx,
resource_provider=ss,
resource_class='DISK_GB',
total=100000,
reserved=0,
max_unit=1000,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
}
# We do a fetch from the DB for each instance to get its latest
# generation. This would be done by the resource tracker or scheduler
# report client before issuing the call to reshape() because the
# consumers representing the two instances above will have had their
# generations incremented in the original call to PUT
# /allocations/{consumer_uuid}
i1_consumer = consumer_obj.Consumer.get_by_uuid(self.ctx, i1_uuid)
after_allocs = rp_obj.AllocationList(
self.ctx,
objects=[
# instance1 gets VCPU from NUMA0, MEMORY_MB from cn1 and DISK_GB
# from the sharing storage provider
rp_obj.Allocation(self.ctx,
resource_provider=cn1_numa0,
resource_class='VCPU',
consumer=i1_consumer,
used=2),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
consumer=i1_consumer,
used=1024),
rp_obj.Allocation(self.ctx,
resource_provider=ss,
resource_class='DISK_GB',
consumer=i1_consumer,
used=100),
])
# OK, now before we call reshape(), here we emulate another thread
# changing the inventory for the sharing storage provider in between
# the time in the REST handler when the sharing storage provider's
# generation was validated and the actual call to reshape()
ss_threadB = rp_obj.ResourceProvider.get_by_uuid(self.ctx, ss.uuid)
# Reduce the amount of storage to 2000, from 100000.
new_ss_inv = rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=ss_threadB,
resource_class='DISK_GB',
total=2000,
reserved=0,
max_unit=1000,
min_unit=1,
step_size=1,
allocation_ratio=1.0)
])
ss_threadB.set_inventory(new_ss_inv)
# Double check our storage provider's generation is now greater than
# the original storage provider record being sent to reshape()
self.assertGreater(ss_threadB.generation, ss.generation)
# And we should legitimately get a failure now to reshape() due to
# another thread updating one of the involved provider's generations
self.assertRaises(exception.ConcurrentUpdateDetected, rp_obj.reshape,
self.ctx, after_inventories, after_allocs)
def test_reshape(self):
"""We set up the following scenario:
BEFORE: single compute node setup
A single compute node with:
- VCPU, MEMORY_MB, DISK_GB inventory
- Two instances consuming CPU, RAM and DISK from that compute node
AFTER: hierarchical + shared storage setup
A compute node parent provider with:
- MEMORY_MB
Two NUMA node child providers containing:
- VCPU
Shared storage provider with:
- DISK_GB
Both instances have their resources split among the providers and
shared storage accordingly
"""
# First create our consumers
i1_uuid = uuids.instance1
i1_consumer = consumer_obj.Consumer(self.ctx,
uuid=i1_uuid,
user=self.user_obj,
project=self.project_obj)
i1_consumer.create()
i2_uuid = uuids.instance2
i2_consumer = consumer_obj.Consumer(self.ctx,
uuid=i2_uuid,
user=self.user_obj,
project=self.project_obj)
i2_consumer.create()
cn1 = self._create_provider('cn1')
tb.add_inventory(cn1, 'VCPU', 16)
tb.add_inventory(cn1, 'MEMORY_MB', 32768)
tb.add_inventory(cn1, 'DISK_GB', 1000)
# Allocate both instances against the single compute node
for consumer in (i1_consumer, i2_consumer):
allocs = [
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='VCPU',
consumer=consumer,
used=2),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
consumer=consumer,
used=1024),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='DISK_GB',
consumer=consumer,
used=100),
]
alloc_list = rp_obj.AllocationList(self.ctx, objects=allocs)
alloc_list.replace_all()
# Verify we have the allocations we expect for the BEFORE scenario
before_allocs_i1 = rp_obj.AllocationList.get_all_by_consumer_id(
self.ctx, i1_uuid)
self.assertEqual(3, len(before_allocs_i1))
self.assertEqual(cn1.uuid, before_allocs_i1[0].resource_provider.uuid)
before_allocs_i2 = rp_obj.AllocationList.get_all_by_consumer_id(
self.ctx, i2_uuid)
self.assertEqual(3, len(before_allocs_i2))
self.assertEqual(cn1.uuid, before_allocs_i2[2].resource_provider.uuid)
# Before we issue the actual reshape() call, we need to first create
# the child providers and sharing storage provider. These are actions
# that the virt driver or external agent is responsible for performing
# *before* attempting any reshape activity.
cn1_numa0 = self._create_provider('cn1_numa0', parent=cn1.uuid)
cn1_numa1 = self._create_provider('cn1_numa1', parent=cn1.uuid)
ss = self._create_provider('ss')
# OK, now emulate the call to POST /reshaper that will be triggered by
# a virt driver wanting to replace the world and change its modeling
# from a single provider to a nested provider tree along with a sharing
# storage provider.
after_inventories = {
# cn1 keeps the RAM only
cn1:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
total=32768,
reserved=0,
max_unit=32768,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
# each NUMA node gets half of the CPUs
cn1_numa0:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=cn1_numa0,
resource_class='VCPU',
total=8,
reserved=0,
max_unit=8,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
cn1_numa1:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(
self.ctx,
resource_provider=cn1_numa1,
resource_class='VCPU',
total=8,
reserved=0,
max_unit=8,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
# The sharing provider gets a bunch of disk
ss:
rp_obj.InventoryList(self.ctx,
objects=[
rp_obj.Inventory(self.ctx,
resource_provider=ss,
resource_class='DISK_GB',
total=100000,
reserved=0,
max_unit=1000,
min_unit=1,
step_size=1,
allocation_ratio=1.0),
]),
}
# We do a fetch from the DB for each instance to get its latest
# generation. This would be done by the resource tracker or scheduler
# report client before issuing the call to reshape() because the
# consumers representing the two instances above will have had their
# generations incremented in the original call to PUT
# /allocations/{consumer_uuid}
i1_consumer = consumer_obj.Consumer.get_by_uuid(self.ctx, i1_uuid)
i2_consumer = consumer_obj.Consumer.get_by_uuid(self.ctx, i2_uuid)
after_allocs = rp_obj.AllocationList(
self.ctx,
objects=[
# instance1 gets VCPU from NUMA0, MEMORY_MB from cn1 and DISK_GB
# from the sharing storage provider
rp_obj.Allocation(self.ctx,
resource_provider=cn1_numa0,
resource_class='VCPU',
consumer=i1_consumer,
used=2),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
consumer=i1_consumer,
used=1024),
rp_obj.Allocation(self.ctx,
resource_provider=ss,
resource_class='DISK_GB',
consumer=i1_consumer,
used=100),
# instance2 gets VCPU from NUMA1, MEMORY_MB from cn1 and DISK_GB
# from the sharing storage provider
rp_obj.Allocation(self.ctx,
resource_provider=cn1_numa1,
resource_class='VCPU',
consumer=i2_consumer,
used=2),
rp_obj.Allocation(self.ctx,
resource_provider=cn1,
resource_class='MEMORY_MB',
consumer=i2_consumer,
used=1024),
rp_obj.Allocation(self.ctx,
resource_provider=ss,
resource_class='DISK_GB',
consumer=i2_consumer,
used=100),
])
rp_obj.reshape(self.ctx, after_inventories, after_allocs)
# Verify that the inventories have been moved to the appropriate
# providers in the AFTER scenario
# The root compute node should only have MEMORY_MB, nothing else
cn1_inv = rp_obj.InventoryList.get_all_by_resource_provider(
self.ctx, cn1)
self.assertEqual(1, len(cn1_inv))
self.assertEqual('MEMORY_MB', cn1_inv[0].resource_class)
self.assertEqual(32768, cn1_inv[0].total)
# Each NUMA node should only have half the original VCPU, nothing else
numa0_inv = rp_obj.InventoryList.get_all_by_resource_provider(
self.ctx, cn1_numa0)
self.assertEqual(1, len(numa0_inv))
self.assertEqual('VCPU', numa0_inv[0].resource_class)
self.assertEqual(8, numa0_inv[0].total)
numa1_inv = rp_obj.InventoryList.get_all_by_resource_provider(
self.ctx, cn1_numa1)
self.assertEqual(1, len(numa1_inv))
self.assertEqual('VCPU', numa1_inv[0].resource_class)
self.assertEqual(8, numa1_inv[0].total)
# The sharing storage provider should only have DISK_GB, nothing else
ss_inv = rp_obj.InventoryList.get_all_by_resource_provider(
self.ctx, ss)
self.assertEqual(1, len(ss_inv))
self.assertEqual('DISK_GB', ss_inv[0].resource_class)
self.assertEqual(100000, ss_inv[0].total)
# Verify we have the allocations we expect for the AFTER scenario
after_allocs_i1 = rp_obj.AllocationList.get_all_by_consumer_id(
self.ctx, i1_uuid)
self.assertEqual(3, len(after_allocs_i1))
# Our VCPU allocation should be in the NUMA0 node
vcpu_alloc = alloc_for_rc(after_allocs_i1, 'VCPU')
self.assertIsNotNone(vcpu_alloc)
self.assertEqual(cn1_numa0.uuid, vcpu_alloc.resource_provider.uuid)
# Our DISK_GB allocation should be in the sharing provider
disk_alloc = alloc_for_rc(after_allocs_i1, 'DISK_GB')
self.assertIsNotNone(disk_alloc)
self.assertEqual(ss.uuid, disk_alloc.resource_provider.uuid)
# And our MEMORY_MB should remain on the root compute node
ram_alloc = alloc_for_rc(after_allocs_i1, 'MEMORY_MB')
self.assertIsNotNone(ram_alloc)
self.assertEqual(cn1.uuid, ram_alloc.resource_provider.uuid)
after_allocs_i2 = rp_obj.AllocationList.get_all_by_consumer_id(
self.ctx, i2_uuid)
self.assertEqual(3, len(after_allocs_i2))
# Our VCPU allocation should be in the NUMA1 node
vcpu_alloc = alloc_for_rc(after_allocs_i2, 'VCPU')
self.assertIsNotNone(vcpu_alloc)
self.assertEqual(cn1_numa1.uuid, vcpu_alloc.resource_provider.uuid)
# Our DISK_GB allocation should be in the sharing provider
disk_alloc = alloc_for_rc(after_allocs_i2, 'DISK_GB')
self.assertIsNotNone(disk_alloc)
self.assertEqual(ss.uuid, disk_alloc.resource_provider.uuid)
# And our MEMORY_MB should remain on the root compute node
ram_alloc = alloc_for_rc(after_allocs_i2, 'MEMORY_MB')
self.assertIsNotNone(ram_alloc)
self.assertEqual(cn1.uuid, ram_alloc.resource_provider.uuid)
def start_fixture(self):
super(SharedStorageFixture, self).start_fixture()
self.context = context.get_admin_context()
cn1_uuid = uuidutils.generate_uuid()
cn2_uuid = uuidutils.generate_uuid()
ss_uuid = uuidutils.generate_uuid()
agg_uuid = uuidutils.generate_uuid()
os.environ['CN1_UUID'] = cn1_uuid
os.environ['CN2_UUID'] = cn2_uuid
os.environ['SS_UUID'] = ss_uuid
os.environ['AGG_UUID'] = agg_uuid
cn1 = rp_obj.ResourceProvider(
self.context,
name='cn1',
uuid=cn1_uuid)
cn1.create()
cn2 = rp_obj.ResourceProvider(
self.context,
name='cn2',
uuid=cn2_uuid)
cn2.create()
ss = rp_obj.ResourceProvider(
self.context,
name='ss',
uuid=ss_uuid)
ss.create()
# Populate compute node inventory for VCPU and RAM
for cn in (cn1, cn2):
vcpu_inv = rp_obj.Inventory(
self.context,
resource_provider=cn,
resource_class='VCPU',
total=24,
reserved=0,
max_unit=24,
min_unit=1,
step_size=1,
allocation_ratio=16.0)
vcpu_inv.obj_set_defaults()
ram_inv = rp_obj.Inventory(
self.context,
resource_provider=cn,
resource_class='MEMORY_MB',
total=128 * 1024,
reserved=0,
max_unit=128 * 1024,
min_unit=256,
step_size=256,
allocation_ratio=1.5)
ram_inv.obj_set_defaults()
inv_list = rp_obj.InventoryList(objects=[vcpu_inv, ram_inv])
cn.set_inventory(inv_list)
t_avx_sse = rp_obj.Trait.get_by_name(self.context, "HW_CPU_X86_SSE")
t_avx_sse2 = rp_obj.Trait.get_by_name(self.context, "HW_CPU_X86_SSE2")
cn1.set_traits(rp_obj.TraitList(objects=[t_avx_sse, t_avx_sse2]))
# Populate shared storage provider with DISK_GB inventory
disk_inv = rp_obj.Inventory(
self.context,
resource_provider=ss,
resource_class='DISK_GB',
total=2000,
reserved=100,
max_unit=2000,
min_unit=10,
step_size=10,
allocation_ratio=1.0)
disk_inv.obj_set_defaults()
inv_list = rp_obj.InventoryList(objects=[disk_inv])
ss.set_inventory(inv_list)
# Mark the shared storage pool as having inventory shared among any
# provider associated via aggregate
t = rp_obj.Trait.get_by_name(
self.context,
"MISC_SHARES_VIA_AGGREGATE",
)
ss.set_traits(rp_obj.TraitList(objects=[t]))
# Now associate the shared storage pool and both compute nodes with the
# same aggregate
cn1.set_aggregates([agg_uuid])
cn2.set_aggregates([agg_uuid])
ss.set_aggregates([agg_uuid])