r.addFlavour(f)
self.assertTrue("test" in r._flavors)
self.assertTrue(r._flavors.get("test").get("testmetric") == 42)
- # test if allocate and free runs through
- self.assertTrue(len(r.allocate("testc", "tiny")) == 3) # expected: 3tuple
- self.assertTrue(r.free("testc"))
def testAddRmToDc(self):
"""
self.assertTrue(len(self.net.rm_registrar.resource_models) == 1)
# check if alloc was called during startCompute
- self.assertTrue(len(r.allocated_compute_instances) == 0)
+ self.assertTrue(len(r._allocated_compute_instances) == 0)
self.dc[0].startCompute("tc1")
time.sleep(1)
- self.assertTrue(len(r.allocated_compute_instances) == 1)
+ self.assertTrue(len(r._allocated_compute_instances) == 1)
# check if free was called during stopCompute
self.dc[0].stopCompute("tc1")
- self.assertTrue(len(r.allocated_compute_instances) == 0)
+ self.assertTrue(len(r._allocated_compute_instances) == 0)
# check connectivity by using ping
self.assertTrue(self.net.ping([self.h[0], self.h[1]]) <= 0.0)
# stop Mininet network
self.stopNet()
+def createDummyContainerObject(name, flavor):
+
+ class DummyContainer(object):
+
+ def __init__(self):
+ self.cpu_period = -1
+ self.cpu_quota = -1
+ self.mem_limit = -1
+ self.memswap_limit = -1
+
+ def updateCpuLimit(self, cpu_period, cpu_quota):
+ self.cpu_period = cpu_period
+ self.cpu_quota = cpu_quota
+
+ def updateMemoryLimit(self, mem_limit):
+ self.mem_limit = mem_limit
+
+ d = DummyContainer()
+ d.name = name
+ d.flavor_name = flavor
+ return d
+
+
+
+
class testUpbSimpleCloudDcRM(SimpleTestTopology):
"""
Test the UpbSimpleCloudDc resource model.
# config
E_CPU = 1.0
MAX_CU = 100
+ E_MEM = 512
+ MAX_MU = 2048
# create dummy resource model environment
- reg = ResourceModelRegistrar(dc_emulation_max_cpu=1.0)
- rm = UpbSimpleCloudDcRM(max_cu=100, max_mu=100)
+ reg = ResourceModelRegistrar(dc_emulation_max_cpu=E_CPU, dc_emulation_max_mem=E_MEM)
+ rm = UpbSimpleCloudDcRM(max_cu=MAX_CU, max_mu=MAX_MU)
reg.register("test_dc", rm)
- res = rm.allocate("c1", "tiny") # calculate allocation
- self.assertTrue(res[0] == E_CPU / MAX_CU * 1) # validate compute result
- self.assertTrue(res[1] < 0) # validate memory result
- self.assertTrue(res[2] < 0) # validate disk result
+ c1 = createDummyContainerObject("c1", flavor="tiny")
+ rm.allocate(c1) # calculate allocation
+ self.assertEqual(float(c1.cpu_quota) / c1.cpu_period, E_CPU / MAX_CU * 0.5) # validate compute result
+ self.assertEqual(float(c1.mem_limit/1024/1024), float(E_MEM) / MAX_MU * 32) # validate memory result
- res = rm.allocate("c2", "small") # calculate allocation
- self.assertTrue(res[0] == E_CPU / MAX_CU * 4) # validate compute result
- self.assertTrue(res[1] < 0) # validate memory result
- self.assertTrue(res[2] < 0) # validate disk result
+ c2 = createDummyContainerObject("c2", flavor="small")
+ rm.allocate(c2) # calculate allocation
+ self.assertEqual(float(c2.cpu_quota) / c2.cpu_period, E_CPU / MAX_CU * 1) # validate compute result
+ self.assertEqual(float(c2.mem_limit/1024/1024), float(E_MEM) / MAX_MU * 128) # validate memory result
- res = rm.allocate("c3", "medium") # calculate allocation
- self.assertTrue(res[0] == E_CPU / MAX_CU * 8) # validate compute result
- self.assertTrue(res[1] < 0) # validate memory result
- self.assertTrue(res[2] < 0) # validate disk result
- res = rm.allocate("c4", "large") # calculate allocation
- self.assertTrue(res[0] == E_CPU / MAX_CU * 16) # validate compute result
- self.assertTrue(res[1] < 0) # validate memory result
- self.assertTrue(res[2] < 0) # validate disk result
+ c3 = createDummyContainerObject("c3", flavor="medium")
+ res = rm.allocate(c3) # calculate allocation
+ self.assertEqual(float(c3.cpu_quota) / c3.cpu_period, E_CPU / MAX_CU * 4) # validate compute result
+ self.assertEqual(float(c3.mem_limit/1024/1024), float(E_MEM) / MAX_MU * 256) # validate memory result
- res = rm.allocate("c5", "xlarge") # calculate allocation
- self.assertTrue(res[0] == E_CPU / MAX_CU * 32) # validate compute result
- self.assertTrue(res[1] < 0) # validate memory result
- self.assertTrue(res[2] < 0) # validate disk result
+
+ c4 = createDummyContainerObject("c4", flavor="large")
+ rm.allocate(c4) # calculate allocation
+ self.assertEqual(float(c4.cpu_quota) / c4.cpu_period, E_CPU / MAX_CU * 8) # validate compute result
+ self.assertEqual(float(c4.mem_limit/1024/1024), float(E_MEM) / MAX_MU * 512) # validate memory result
+
+
+ c5 = createDummyContainerObject("c5", flavor="xlarge")
+ rm.allocate(c5) # calculate allocation
+ self.assertEqual(float(c5.cpu_quota) / c5.cpu_period, E_CPU / MAX_CU * 16) # validate compute result
+ self.assertEqual(float(c5.mem_limit/1024/1024), float(E_MEM) / MAX_MU * 1024) # validate memory result
+
+
+ def testAllocationCpuLimit(self):
+ """
+ Test CPU allocation limit
+ :return:
+ """
+ # config
+ E_CPU = 1.0
+ MAX_CU = 40
+ E_MEM = 512
+ MAX_MU = 4096
+ # create dummy resource model environment
+ reg = ResourceModelRegistrar(dc_emulation_max_cpu=E_CPU, dc_emulation_max_mem=E_MEM)
+ rm = UpbSimpleCloudDcRM(max_cu=MAX_CU, max_mu=MAX_MU)
+ reg.register("test_dc", rm)
+
+ # test over provisioning exeption
+ exception = False
+ try:
+ c6 = createDummyContainerObject("c6", flavor="xlarge")
+ c7 = createDummyContainerObject("c7", flavor="xlarge")
+ c8 = createDummyContainerObject("c8", flavor="xlarge")
+ c9 = createDummyContainerObject("c9", flavor="xlarge")
+ rm.allocate(c6) # calculate allocation
+ rm.allocate(c7) # calculate allocation
+ rm.allocate(c8) # calculate allocation
+ rm.allocate(c9) # calculate allocation
+ except Exception as e:
+ self.assertIn("Not enough compute", e.message)
+ exception = True
+ self.assertTrue(exception)
+
+ def testAllocationMemLimit(self):
+ """
+ Test MEM allocation limit
+ :return:
+ """
+ # config
+ E_CPU = 1.0
+ MAX_CU = 500
+ E_MEM = 512
+ MAX_MU = 2048
+ # create dummy resource model environment
+ reg = ResourceModelRegistrar(dc_emulation_max_cpu=E_CPU, dc_emulation_max_mem=E_MEM)
+ rm = UpbSimpleCloudDcRM(max_cu=MAX_CU, max_mu=MAX_MU)
+ reg.register("test_dc", rm)
# test over provisioning exeption
exception = False
try:
- rm.allocate("c6", "xlarge") # calculate allocation
- rm.allocate("c7", "xlarge") # calculate allocation
- rm.allocate("c8", "xlarge") # calculate allocation
- rm.allocate("c9", "xlarge") # calculate allocation
+ c6 = createDummyContainerObject("c6", flavor="xlarge")
+ c7 = createDummyContainerObject("c7", flavor="xlarge")
+ c8 = createDummyContainerObject("c8", flavor="xlarge")
+ rm.allocate(c6) # calculate allocation
+ rm.allocate(c7) # calculate allocation
+ rm.allocate(c8) # calculate allocation
except Exception as e:
- self.assertTrue("Not enough compute" in e.message)
+ self.assertIn("Not enough memory", e.message)
exception = True
self.assertTrue(exception)
E_CPU = 1.0
MAX_CU = 100
# create dummy resource model environment
- reg = ResourceModelRegistrar(dc_emulation_max_cpu=1.0)
+ reg = ResourceModelRegistrar(dc_emulation_max_cpu=1.0, dc_emulation_max_mem=512)
rm = UpbSimpleCloudDcRM(max_cu=100, max_mu=100)
reg.register("test_dc", rm)
- rm.allocate("c1", "tiny") # calculate allocation
- self.assertTrue(rm.dc_alloc_cu == 1)
- rm.free("c1")
+ c1 = createDummyContainerObject("c6", flavor="tiny")
+ rm.allocate(c1) # calculate allocation
+ self.assertTrue(rm.dc_alloc_cu == 0.5)
+ rm.free(c1)
self.assertTrue(rm.dc_alloc_cu == 0)
def testInRealTopo(self):
self.assertTrue(len(self.net.rm_registrar.resource_models) == 1)
# check if alloc was called during startCompute
- self.assertTrue(len(r.allocated_compute_instances) == 0)
+ self.assertTrue(len(r._allocated_compute_instances) == 0)
tc1 = self.dc[0].startCompute("tc1", flavor_name="tiny")
time.sleep(1)
- self.assertTrue(len(r.allocated_compute_instances) == 1)
+ self.assertTrue(len(r._allocated_compute_instances) == 1)
# check if there is a real limitation set for containers cgroup
- self.assertEqual(tc1.cpu_period/tc1.cpu_quota, 100)
+ self.assertEqual(float(tc1.cpu_quota)/tc1.cpu_period, 0.005)
# check if free was called during stopCompute
self.dc[0].stopCompute("tc1")
- self.assertTrue(len(r.allocated_compute_instances) == 0)
+ self.assertTrue(len(r._allocated_compute_instances) == 0)
# check connectivity by using ping
self.assertTrue(self.net.ping([self.h[0], self.h[1]]) <= 0.0)
# stop Mininet network