use of org.btrplace.model.view.network.Network in project scheduler by btrplace.
the class CPrecedenceTest method testOk.
@Test
public void testOk() throws SchedulerException {
// New default model
Model mo = new DefaultModel();
Mapping ma = mo.getMapping();
// Create and boot 2 source nodes and 1 destination node
Node srcNode1 = mo.newNode(), srcNode2 = mo.newNode(), dstNode = mo.newNode();
ma.addOnlineNode(srcNode1);
ma.addOnlineNode(srcNode2);
ma.addOnlineNode(dstNode);
// Attach a network view
Network net = new Network();
mo.attach(net);
// Connect the nodes through a main non-blocking switch
// The destination node have twice the bandwidth of source nodes
Switch swMain = net.newSwitch();
net.connect(1000, swMain, srcNode1, srcNode2);
net.connect(2000, swMain, dstNode);
// Create and host 1 VM per source node
VM vm1 = mo.newVM();
VM vm2 = mo.newVM();
ma.addRunningVM(vm1, srcNode1);
ma.addRunningVM(vm2, srcNode2);
// Attach CPU and Mem resource views and assign nodes capacity and VMs consumption
int mem_vm = 8, cpu_vm = 4, mem_src = 8, cpu_src = 4, mem_dst = 16, cpu_dst = 8;
ShareableResource rcMem = new ShareableResource("mem", 0, 0), rcCPU = new ShareableResource("cpu", 0, 0);
mo.attach(rcMem);
mo.attach(rcCPU);
// VMs
rcMem.setConsumption(vm1, mem_vm).setConsumption(vm2, mem_vm);
rcCPU.setConsumption(vm1, cpu_vm).setConsumption(vm2, cpu_vm);
// Nodes
rcMem.setCapacity(srcNode1, mem_src).setCapacity(srcNode2, mem_src).setCapacity(dstNode, mem_dst);
rcCPU.setCapacity(srcNode1, cpu_src).setCapacity(srcNode2, cpu_src).setCapacity(dstNode, cpu_dst);
// Set VM attributes 'memory used', 'hot dirty page size', 'hot dirty page duration' and 'cold dirty pages rate'
int vm_mu = 6000, vm_mds = 46, vm_mdd = 2;
double vm_cdr = 23.6;
// vm1 is an 'idle' VM (with no special memory activity) but still consumes 6 GiB of memory
mo.getAttributes().put(vm1, "memUsed", vm_mu);
// vm2 consumes 6 GiB memory and has a memory intensive workload equivalent to "stress --vm 1000 --bytes 50K"
// VM with a workload
mo.getAttributes().put(vm2, "memUsed", vm_mu);
mo.getAttributes().put(vm2, "hotDirtySize", vm_mds);
mo.getAttributes().put(vm2, "hotDirtyDuration", vm_mdd);
mo.getAttributes().put(vm2, "coldDirtyRate", vm_cdr);
// Create constraints
List<SatConstraint> cstrs = new ArrayList<>();
// Placement constraints, we want to shutdown the source nodes to force the migration to destination nodes
cstrs.add(new Offline(srcNode1));
cstrs.add(new Offline(srcNode2));
// MIGRATE VM2 BEFORE VM1
Precedence prec = new Precedence(vm2, vm1);
cstrs.add(prec);
// Solve it using the Min Max Time To Repair Migration scheduling oriented objective
ReconfigurationPlan p = new DefaultChocoScheduler().solve(mo, cstrs, new MinMTTRMig());
Assert.assertNotNull(p);
// Check if the precedence constraint is respected
Action mig1 = p.getActions().stream().filter(s -> s instanceof MigrateVM && ((MigrateVM) s).getVM().equals(vm1)).findAny().get();
Action mig2 = p.getActions().stream().filter(s -> s instanceof MigrateVM && ((MigrateVM) s).getVM().equals(vm2)).findAny().get();
Assert.assertTrue(mig1.getStart() >= mig2.getEnd());
// TODO: use methods on PrecedenceChecker to verify that the migrations are in the expected order ?
Assert.assertTrue(prec.isSatisfied(p));
}
use of org.btrplace.model.view.network.Network in project scheduler by btrplace.
the class CSerializeTest method testOk.
@Test
public void testOk() throws SchedulerException {
// New default model
Model mo = new DefaultModel();
Mapping ma = mo.getMapping();
// Create and boot 2 source nodes and 1 destination node
Node srcNode1 = mo.newNode(), srcNode2 = mo.newNode(), dstNode = mo.newNode();
ma.addOnlineNode(srcNode1);
ma.addOnlineNode(srcNode2);
ma.addOnlineNode(dstNode);
// Attach a network view
Network net = new Network();
mo.attach(net);
// Connect the nodes through a main non-blocking switch
// The destination node have twice the bandwidth of source nodes
Switch swMain = net.newSwitch();
net.connect(1000, swMain, srcNode1, srcNode2);
net.connect(2000, swMain, dstNode);
// Create and host 1 VM per source node
VM vm1 = mo.newVM();
VM vm2 = mo.newVM();
ma.addRunningVM(vm1, srcNode1);
ma.addRunningVM(vm2, srcNode2);
// Attach CPU and Mem resource views and assign nodes capacity and VMs consumption
int mem_vm = 8, cpu_vm = 4, mem_src = 8, cpu_src = 4, mem_dst = 16, cpu_dst = 8;
ShareableResource rcMem = new ShareableResource("mem", 0, 0), rcCPU = new ShareableResource("cpu", 0, 0);
mo.attach(rcMem);
mo.attach(rcCPU);
// VMs
rcMem.setConsumption(vm1, mem_vm).setConsumption(vm2, mem_vm);
rcCPU.setConsumption(vm1, cpu_vm).setConsumption(vm2, cpu_vm);
// Nodes
rcMem.setCapacity(srcNode1, mem_src).setCapacity(srcNode2, mem_src).setCapacity(dstNode, mem_dst);
rcCPU.setCapacity(srcNode1, cpu_src).setCapacity(srcNode2, cpu_src).setCapacity(dstNode, cpu_dst);
// Set VM attributes 'memory used', 'hot dirty page size', 'hot dirty page duration' and 'cold dirty pages rate'
int vm_mu = 6000, vm_mds = 46, vm_mdd = 2;
double vm_cdr = 23.6;
// vm1 is an 'idle' VM (with no special memory activity) but still consumes 6 GiB of memory
mo.getAttributes().put(vm1, "memUsed", vm_mu);
// vm2 consumes 6 GiB memory and has a memory intensive workload equivalent to "stress --vm 1000 --bytes 50K"
// VM with a workload
mo.getAttributes().put(vm2, "memUsed", vm_mu);
mo.getAttributes().put(vm2, "hotDirtySize", vm_mds);
mo.getAttributes().put(vm2, "hotDirtyDuration", vm_mdd);
mo.getAttributes().put(vm2, "coldDirtyRate", vm_cdr);
// Create constraints
List<SatConstraint> cstrs = new ArrayList<>();
// Placement constraints, we want to shutdown the source nodes to force the migration to destination nodes
cstrs.add(new Offline(srcNode1));
cstrs.add(new Offline(srcNode2));
// SERIALIZE THE TWO MIGRATIONS
Serialize serial = new Serialize(vm1, vm2);
cstrs.add(serial);
// Solve it using the Min Max Time To Repair Migration scheduling oriented objective
ReconfigurationPlan p = new DefaultChocoScheduler().solve(mo, cstrs, new MinMTTRMig());
Assert.assertNotNull(p);
// Check if the serialize constraint is respected
MigrateVM mig1 = (MigrateVM) p.getActions().stream().filter(s -> s instanceof MigrateVM && ((MigrateVM) s).getVM().equals(vm1)).findAny().get();
MigrateVM mig2 = (MigrateVM) p.getActions().stream().filter(s -> s instanceof MigrateVM && ((MigrateVM) s).getVM().equals(vm2)).findAny().get();
Assert.assertTrue(mig1.getStart() >= mig2.getEnd() || mig2.getStart() >= mig1.getEnd());
// TODO: use methods on SerializeChecker to verify that the actions are serialized ?
Assert.assertTrue(serial.isSatisfied(p));
}
use of org.btrplace.model.view.network.Network in project scheduler by btrplace.
the class CSyncTest method testOk.
@Test
public void testOk() throws SchedulerException {
// New default model
Model mo = new DefaultModel();
Mapping ma = mo.getMapping();
// Create and boot 2 source nodes and 1 destination node
Node srcNode1 = mo.newNode(), srcNode2 = mo.newNode(), dstNode = mo.newNode();
ma.addOnlineNode(srcNode1);
ma.addOnlineNode(srcNode2);
ma.addOnlineNode(dstNode);
// Attach a network view
Network net = new Network();
mo.attach(net);
// Connect the nodes through a main non-blocking switch
// The destination node have twice the bandwidth of source nodes
Switch swMain = net.newSwitch();
net.connect(1000, swMain, srcNode1, srcNode2);
net.connect(2000, swMain, dstNode);
// Create and host 1 VM per source node
VM vm1 = mo.newVM();
VM vm2 = mo.newVM();
ma.addRunningVM(vm1, srcNode1);
ma.addRunningVM(vm2, srcNode2);
// Attach CPU and Mem resource views and assign nodes capacity and VMs consumption
int mem_vm = 8, cpu_vm = 4, mem_src = 8, cpu_src = 4, mem_dst = 16, cpu_dst = 8;
ShareableResource rcMem = new ShareableResource("mem", 0, 0), rcCPU = new ShareableResource("cpu", 0, 0);
mo.attach(rcMem);
mo.attach(rcCPU);
// VMs
rcMem.setConsumption(vm1, mem_vm).setConsumption(vm2, mem_vm);
rcCPU.setConsumption(vm1, cpu_vm).setConsumption(vm2, cpu_vm);
// Nodes
rcMem.setCapacity(srcNode1, mem_src).setCapacity(srcNode2, mem_src).setCapacity(dstNode, mem_dst);
rcCPU.setCapacity(srcNode1, cpu_src).setCapacity(srcNode2, cpu_src).setCapacity(dstNode, cpu_dst);
// Set VM attributes 'memory used', 'hot dirty page size', 'hot dirty page duration' and 'cold dirty pages rate'
int vm_mu = 6000, vm_mds = 46, vm_mdd = 2;
double vm_cdr = 23.6;
// vm1 is an 'idle' VM (with no special memory activity) but still consumes 6 GiB of memory
mo.getAttributes().put(vm1, "memUsed", vm_mu);
// vm2 consumes 6 GiB memory and has a memory intensive workload equivalent to "stress --vm 1000 --bytes 50K"
// VM with a workload
mo.getAttributes().put(vm2, "memUsed", vm_mu);
mo.getAttributes().put(vm2, "hotDirtySize", vm_mds);
mo.getAttributes().put(vm2, "hotDirtyDuration", vm_mdd);
mo.getAttributes().put(vm2, "coldDirtyRate", vm_cdr);
// Create constraints
List<SatConstraint> cstrs = new ArrayList<>();
// Placement constraints, we want to shutdown the source nodes to force the migration to destination nodes
cstrs.add(new Offline(srcNode1));
cstrs.add(new Offline(srcNode2));
// SYNCHRONIZE THE TWO MIGRATIONS
Sync sync = new Sync(vm1, vm2);
cstrs.add(sync);
// Solve it using the Min Max Time To Repair Migration scheduling oriented objective
ReconfigurationPlan p = new DefaultChocoScheduler().solve(mo, cstrs, new MinMTTRMig());
// It works BUT the VMs are synchronized by default (thanks to BW optimization), is Sync a useless constraint ?
Assert.assertNotNull(p);
// Check if the sync constraint is respected
Action mig1 = p.getActions().stream().filter(s -> s instanceof MigrateVM && ((MigrateVM) s).getVM().equals(vm1)).findAny().get();
Action mig2 = p.getActions().stream().filter(s -> s instanceof MigrateVM && ((MigrateVM) s).getVM().equals(vm2)).findAny().get();
Assert.assertTrue(mig1.getEnd() == mig2.getEnd());
// TODO: use methods on SyncChecker to verify that the actions are synchronized ?
Assert.assertTrue(sync.isSatisfied(p));
}
use of org.btrplace.model.view.network.Network in project scheduler by btrplace.
the class CSyncTest method testKo.
@Test
public void testKo() throws SchedulerException {
// New default model
Model mo = new DefaultModel();
Mapping ma = mo.getMapping();
// Create and boot 2 source nodes and 1 destination node
Node srcNode1 = mo.newNode(), srcNode2 = mo.newNode(), dstNode = mo.newNode();
ma.addOnlineNode(srcNode1);
ma.addOnlineNode(srcNode2);
ma.addOnlineNode(dstNode);
// Attach a network view
Network net = new Network();
mo.attach(net);
// Connect the nodes through a main non-blocking switch with 1 Gbit/s links
Switch swMain = net.newSwitch();
net.connect(1000, swMain, srcNode1, srcNode2);
net.connect(1000, swMain, dstNode);
// Create and host 1 VM per source node
VM vm1 = mo.newVM();
VM vm2 = mo.newVM();
ma.addRunningVM(vm1, srcNode1);
ma.addRunningVM(vm2, srcNode2);
// Attach CPU and Mem resource views and assign nodes capacity and VMs consumption
int mem_vm = 8, cpu_vm = 4, mem_src = 8, cpu_src = 4, mem_dst = 16, cpu_dst = 8;
ShareableResource rcMem = new ShareableResource("mem", 0, 0), rcCPU = new ShareableResource("cpu", 0, 0);
mo.attach(rcMem);
mo.attach(rcCPU);
// VMs
rcMem.setConsumption(vm1, mem_vm).setConsumption(vm2, mem_vm);
rcCPU.setConsumption(vm1, cpu_vm).setConsumption(vm2, cpu_vm);
// Nodes
rcMem.setCapacity(srcNode1, mem_src).setCapacity(srcNode2, mem_src).setCapacity(dstNode, mem_dst);
rcCPU.setCapacity(srcNode1, cpu_src).setCapacity(srcNode2, cpu_src).setCapacity(dstNode, cpu_dst);
// Set VM attributes 'memory used', 'hot dirty page size', 'hot dirty page duration' and 'cold dirty pages rate'
int vm_mu = 6000, vm_mds = 46, vm_mdd = 2;
double vm_cdr = 23.6;
// vm1 is an 'idle' VM (with no special memory activity) but still consumes 6 GiB of memory
mo.getAttributes().put(vm1, "memUsed", vm_mu);
// vm2 consumes 6 GiB memory and has a memory intensive workload equivalent to "stress --vm 1000 --bytes 50K"
// VM with a workload
mo.getAttributes().put(vm2, "memUsed", vm_mu);
mo.getAttributes().put(vm2, "hotDirtySize", vm_mds);
mo.getAttributes().put(vm2, "hotDirtyDuration", vm_mdd);
mo.getAttributes().put(vm2, "coldDirtyRate", vm_cdr);
// Create constraints
List<SatConstraint> cstrs = new ArrayList<>();
// Placement constraints, we want to shutdown the source nodes to force the migration to destination nodes
cstrs.add(new Offline(srcNode1));
cstrs.add(new Offline(srcNode2));
// TRY TO SYNCHRONIZE THE TWO MIGRATIONS
Sync sync = new Sync(vm1, vm2);
cstrs.add(sync);
// Solve it using the Min Max Time To Repair Migration scheduling oriented objective
ChocoScheduler sched = new DefaultChocoScheduler();
ReconfigurationPlan p = sched.solve(mo, cstrs, new MinMTTRMig());
// Unable to sync two migrations on the same path !
Assert.assertNull(p);
}
use of org.btrplace.model.view.network.Network in project scheduler by btrplace.
the class UCC15 method decommissioning_100gb.
public SolvingStatistics decommissioning_100gb() throws SchedulerException {
// Set nb of nodes and vms
int nbNodesRack = 24;
int nbSrcNodes = nbNodesRack * 20;
int nbDstNodes = nbNodesRack * 10;
int nbVMs = nbSrcNodes * 2;
// Set mem + cpu for VMs and Nodes
int memVM = 4, cpuVM = 1;
int memSrcNode = 16, cpuSrcNode = 4;
int memDstNode = 16, cpuDstNode = 4;
// Set memoryUsed and dirtyRate (for all VMs)
int tpl1MemUsed = 2000, tpl1MaxDirtySize = 5, tpl1MaxDirtyDuration = 3;
// idle vm
double tpl1DirtyRate = 0;
int tpl2MemUsed = 4000, tpl2MaxDirtySize = 96, tpl2MaxDirtyDuration = 2;
// stress --vm 1000 --bytes 70K
double tpl2DirtyRate = 3;
int tpl3MemUsed = 2000, tpl3MaxDirtySize = 96, tpl3MaxDirtyDuration = 2;
// stress --vm 1000 --bytes 70K
double tpl3DirtyRate = 3;
int tpl4MemUsed = 4000, tpl4MaxDirtySize = 5, tpl4MaxDirtyDuration = 3;
// idle vm
double tpl4DirtyRate = 0;
// New default model
Model mo = new DefaultModel();
Mapping ma = mo.getMapping();
// Create online source nodes and offline destination nodes
List<Node> srcNodes = new ArrayList<>(), dstNodes = new ArrayList<>();
for (int i = 0; i < nbSrcNodes; i++) {
srcNodes.add(mo.newNode());
ma.addOnlineNode(srcNodes.get(i));
}
for (int i = 0; i < nbDstNodes; i++) {
dstNodes.add(mo.newNode());
ma.addOfflineNode(dstNodes.get(i));
}
// Set boot and shutdown time
for (Node n : dstNodes) {
mo.getAttributes().put(n, "boot", 1);
/*~2 minutes to boot*/
}
for (Node n : srcNodes) {
mo.getAttributes().put(n, "shutdown", 1);
/*~30 seconds to shutdown*/
}
// Create running VMs on src nodes
List<VM> vms = new ArrayList<>();
VM v;
for (int i = 0; i < nbSrcNodes; i++) {
if (i % 2 == 0) {
v = mo.newVM();
vms.add(v);
mo.getAttributes().put(v, "memUsed", tpl1MemUsed);
mo.getAttributes().put(v, "coldDirtyRate", tpl1DirtyRate);
mo.getAttributes().put(v, "hotDirtySize", tpl1MaxDirtySize);
mo.getAttributes().put(v, "hotDirtyDuration", tpl1MaxDirtyDuration);
ma.addRunningVM(v, srcNodes.get(i));
v = mo.newVM();
vms.add(v);
mo.getAttributes().put(v, "memUsed", tpl2MemUsed);
mo.getAttributes().put(v, "coldDirtyRate", tpl2DirtyRate);
mo.getAttributes().put(v, "hotDirtySize", tpl2MaxDirtySize);
mo.getAttributes().put(v, "hotDirtyDuration", tpl2MaxDirtyDuration);
ma.addRunningVM(v, srcNodes.get(i));
} else {
v = mo.newVM();
vms.add(v);
mo.getAttributes().put(v, "memUsed", tpl3MemUsed);
mo.getAttributes().put(v, "coldDirtyRate", tpl3DirtyRate);
mo.getAttributes().put(v, "hotDirtySize", tpl3MaxDirtySize);
mo.getAttributes().put(v, "hotDirtyDuration", tpl3MaxDirtyDuration);
ma.addRunningVM(v, srcNodes.get(i));
v = mo.newVM();
vms.add(v);
mo.getAttributes().put(v, "memUsed", tpl4MemUsed);
mo.getAttributes().put(v, "coldDirtyRate", tpl4DirtyRate);
mo.getAttributes().put(v, "hotDirtySize", tpl4MaxDirtySize);
mo.getAttributes().put(v, "hotDirtyDuration", tpl4MaxDirtyDuration);
ma.addRunningVM(v, srcNodes.get(i));
}
}
// Add resource decorators
ShareableResource rcMem = new ShareableResource("mem", 0, 0);
ShareableResource rcCPU = new ShareableResource("cpu", 0, 0);
for (Node n : srcNodes) {
rcMem.setCapacity(n, memSrcNode);
rcCPU.setCapacity(n, cpuSrcNode);
}
for (Node n : dstNodes) {
rcMem.setCapacity(n, memDstNode);
rcCPU.setCapacity(n, cpuDstNode);
}
for (VM vm : vms) {
rcMem.setConsumption(vm, memVM);
rcCPU.setConsumption(vm, cpuVM);
}
// mo.attach(rcMem);
// mo.attach(rcCPU);
// Add a NetworkView view
Network net = new Network();
Switch swSrcRack1 = net.newSwitch();
Switch swSrcRack2 = net.newSwitch();
Switch swSrcRack3 = net.newSwitch();
Switch swSrcRack4 = net.newSwitch();
Switch swSrcRack5 = net.newSwitch();
Switch swSrcRack6 = net.newSwitch();
Switch swSrcRack7 = net.newSwitch();
Switch swSrcRack8 = net.newSwitch();
Switch swSrcRack9 = net.newSwitch();
Switch swSrcRack10 = net.newSwitch();
Switch swSrcRack11 = net.newSwitch();
Switch swSrcRack12 = net.newSwitch();
Switch swSrcRack13 = net.newSwitch();
Switch swSrcRack14 = net.newSwitch();
Switch swSrcRack15 = net.newSwitch();
Switch swSrcRack16 = net.newSwitch();
Switch swSrcRack17 = net.newSwitch();
Switch swSrcRack18 = net.newSwitch();
Switch swSrcRack19 = net.newSwitch();
Switch swSrcRack20 = net.newSwitch();
Switch swDstRack1 = net.newSwitch();
Switch swDstRack2 = net.newSwitch();
Switch swDstRack3 = net.newSwitch();
Switch swDstRack4 = net.newSwitch();
Switch swDstRack5 = net.newSwitch();
Switch swDstRack6 = net.newSwitch();
Switch swDstRack7 = net.newSwitch();
Switch swDstRack8 = net.newSwitch();
Switch swDstRack9 = net.newSwitch();
Switch swDstRack10 = net.newSwitch();
Switch swMain = net.newSwitch();
net.connect(1000, swSrcRack1, srcNodes.subList(0, nbNodesRack));
net.connect(1000, swSrcRack2, srcNodes.subList(nbNodesRack, nbNodesRack * 2));
net.connect(1000, swSrcRack3, srcNodes.subList(nbNodesRack * 2, nbNodesRack * 3));
net.connect(1000, swSrcRack4, srcNodes.subList(nbNodesRack * 3, nbNodesRack * 4));
net.connect(1000, swSrcRack5, srcNodes.subList(nbNodesRack * 4, nbNodesRack * 5));
net.connect(1000, swSrcRack6, srcNodes.subList(nbNodesRack * 5, nbNodesRack * 6));
net.connect(1000, swSrcRack7, srcNodes.subList(nbNodesRack * 6, nbNodesRack * 7));
net.connect(1000, swSrcRack8, srcNodes.subList(nbNodesRack * 7, nbNodesRack * 8));
net.connect(1000, swSrcRack9, srcNodes.subList(nbNodesRack * 8, nbNodesRack * 9));
net.connect(1000, swSrcRack10, srcNodes.subList(nbNodesRack * 9, nbNodesRack * 10));
net.connect(1000, swSrcRack11, srcNodes.subList(nbNodesRack * 10, nbNodesRack * 11));
net.connect(1000, swSrcRack12, srcNodes.subList(nbNodesRack * 11, nbNodesRack * 12));
net.connect(1000, swSrcRack13, srcNodes.subList(nbNodesRack * 12, nbNodesRack * 13));
net.connect(1000, swSrcRack14, srcNodes.subList(nbNodesRack * 13, nbNodesRack * 14));
net.connect(1000, swSrcRack15, srcNodes.subList(nbNodesRack * 14, nbNodesRack * 15));
net.connect(1000, swSrcRack16, srcNodes.subList(nbNodesRack * 15, nbNodesRack * 16));
net.connect(1000, swSrcRack17, srcNodes.subList(nbNodesRack * 16, nbNodesRack * 17));
net.connect(1000, swSrcRack18, srcNodes.subList(nbNodesRack * 17, nbNodesRack * 18));
net.connect(1000, swSrcRack19, srcNodes.subList(nbNodesRack * 18, nbNodesRack * 19));
net.connect(1000, swSrcRack20, srcNodes.subList(nbNodesRack * 19, nbNodesRack * 20));
net.connect(1000, swDstRack1, dstNodes.subList(0, nbNodesRack));
net.connect(1000, swDstRack2, dstNodes.subList(nbNodesRack, nbNodesRack * 2));
net.connect(1000, swDstRack3, dstNodes.subList(nbNodesRack * 2, nbNodesRack * 3));
net.connect(1000, swDstRack4, dstNodes.subList(nbNodesRack * 3, nbNodesRack * 4));
net.connect(1000, swDstRack5, dstNodes.subList(nbNodesRack * 4, nbNodesRack * 5));
net.connect(1000, swDstRack6, dstNodes.subList(nbNodesRack * 5, nbNodesRack * 6));
net.connect(1000, swDstRack7, dstNodes.subList(nbNodesRack * 6, nbNodesRack * 7));
net.connect(1000, swDstRack8, dstNodes.subList(nbNodesRack * 7, nbNodesRack * 8));
net.connect(1000, swDstRack9, dstNodes.subList(nbNodesRack * 8, nbNodesRack * 9));
net.connect(1000, swDstRack10, dstNodes.subList(nbNodesRack * 9, nbNodesRack * 10));
net.connect(100000, swMain, swSrcRack1, swSrcRack2, swSrcRack3, swSrcRack4, swSrcRack5, swSrcRack6, swSrcRack7, swSrcRack8, swSrcRack9, swSrcRack10, swSrcRack11, swSrcRack12, swSrcRack13, swSrcRack14, swSrcRack15, swSrcRack16, swSrcRack17, swSrcRack18, swSrcRack19, swSrcRack20, swDstRack1, swDstRack2, swDstRack3, swDstRack4, swDstRack5, swDstRack6, swDstRack7, swDstRack8, swDstRack9, swDstRack10);
mo.attach(net);
// net.generateDot(path + "topology.dot", false);
// Set parameters
DefaultParameters ps = new DefaultParameters();
ps.setVerbosity(0);
ps.setTimeLimit(0);
// ps.setMaxEnd(600);
ps.doOptimize(false);
// Migrate all VMs to destination nodes
List<SatConstraint> cstrs = new ArrayList<>();
int vm_num = 0;
for (int i = 0; i < nbDstNodes; i++) {
cstrs.add(new Fence(vms.get(vm_num), Collections.singleton(dstNodes.get(i))));
cstrs.add(new Fence(vms.get(vm_num + 1), Collections.singleton(dstNodes.get(i))));
cstrs.add(new Fence(vms.get(nbVMs - 1 - vm_num), Collections.singleton(dstNodes.get(i))));
cstrs.add(new Fence(vms.get(nbVMs - 2 - vm_num), Collections.singleton(dstNodes.get(i))));
vm_num += 2;
}
// Shutdown source nodes
cstrs.addAll(srcNodes.stream().map(Offline::new).collect(Collectors.toList()));
// Set a custom objective
DefaultChocoScheduler sc = new DefaultChocoScheduler(ps);
Instance i = new Instance(mo, cstrs, new MinMTTRMig());
ReconfigurationPlan p;
try {
p = sc.solve(i);
System.out.println(sc.getStatistics());
Assert.assertNotNull(p);
} catch (Exception e) {
e.printStackTrace();
}
// finally {
return sc.getStatistics();
// }
}
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