Global Overlay Network : PlanetLab

Global Overlay Network : PlanetLab

Claudio E.Righetti

6 October, 2005

(some slides taken from Larry Peterson)

• “PlanetLab: An Overlay Testbed for Broad-Coverage Services “ Bavier, Bowman, Chun, Culler, Peterson, Roscoe, Wawrzoniak . ACM SIGCOMM Computer Communications Review . Volume 33 Number 3 : July 2003

• “ Overcoming the Internet Impasse through Virtualization “ Anderson , Peterson , Shenker , Turner . IEEE Computer. April 2005

• “Towards a Comprehensive PlanetLab Architecture”, Larry Peterson, Andy Bavier, Marc Fiuczynski, Steve Muir, and Timothy Roscoe, June 2005

http://www.planet-lab.org/PDN/PDN-05-030

Overview

1. What is PlanetLab?

2. Architecture1. Local: Nodes

2. Global: Network

3. Details1. Virtual Machines

2. Maintenance

What Is PlanetLab?

• Geographically distributed overlay network

• Testbed for broad-coverage network services

PlanetLab Goal

“…to support seamless migration of an application from an early prototype,

through multiple design iterations,

to a popular service that continues to evolve.”

Priorities

• Diversity of Network– Geographic– Links

• Edge-sites, co-location and routing centers, homes (DSL, cable-modem)

• Flexibility– Allow experimenters maximal control over PlanetLab nodes– Securely and fairly

Architecture Overview

• Slice : horizontal cut of global PlanetLab resources• Service : set of distributed and cooperating programs

delivering some higher-level functionality• Each service runs in a slice of PlanetLab

Services Run in Slices

PlanetLab Nodes

Services Run in Slices

PlanetLab Nodes

Virtual Machines

Service / Slice A

Services Run in Slices

PlanetLab Nodes

Virtual Machines

Service / Slice A

Service / Slice B

Services Run in Slices

PlanetLab Nodes

Virtual Machines

Service / Slice A

Service / Slice B

Service / Slice C

“… to view slice as a network of

Virtual Machines, with a set of local resources bound to each

VM .”

Virtual Machine Monitor ( VMM)

• Multiple VMs run on each PlanetLab node• VMM arbitrates the nodes’s resources among them

PlanetLab Architecture

• Node-level– Several virtual machines on each node, each running a

different service• Resources distributed fairly• Services are isolated from each other

• Network-level– Node managers, agents, brokers, and service managers

provide interface and maintain PlanetLab

Per-Node View

Virtual Machine Monitor (VMM)

NodeMgr

LocalAdmin

VM1 VM2 VMn…

Node Architecture Goals

• Provide a virtual machine for each service running on a node

• Isolate virtual machines• Allow maximal control over virtual machines• Fair allocation of resources

– Network, CPU, memory, disk

PlanetLab’s design philosophy

• Application Programming Interface used by tipical services

• Protection Interface implemented by the VMM

PlanetLab node virtualization mechanisms are characterized by the these two interfaces are drawn

One Extreme: Software Runtimes (e.g., Java Virtual Machine, MS CLR)

• Very High level API• Depend on OS to provide protection and resource

allocation• Not flexible

Other Extreme: Complete Virtual Machine (e.g., VMware)

• Very Low level API (hardware)– Maximum flexibility

• Excellent protection• High CPU/Memory overhead

– Cannot share common resources among virtual machines• OS, common filesystem

• High-end commercial server , 10s VM

Mainstream Operating System

• API and protection at same level (system calls)• Simple implementation (e.g., Slice = process group)• Efficient use of resources (shared memory, common

OS)• Bad protection and isolation• Maximum Control and Security?

PlanetLab Virtualization: VServers

• Kernel patch to mainstream OS (Linux)• Gives appearance of separate kernel for each virtual

machine– Root privileges restricted to activities that do not affect other

vservers

• Some modification: resource control (e.g., File handles, port numbers) and protection facilities added

PlanetLab Network Architecture

• Node manger (one per node)– Create slices for service managers

• When service managers provide valid tickets

– Allocate resources for vservers

• Resource Monitor (one per node)– Track node’s available resources– Tell agents about available resources

PlanetLab Network Architecture

• Agent (centralized)– Track nodes’ free resources– Advertise resources to resource brokers– Issue tickets to resource brokers

• Tickets may be redeemed with node managers to obtain the resource

PlanetLab Network Architecture

• Resource Broker (per service)– Obtain tickets from agents on behalf of service managers

• Service Manager (per service)– Obtain tickets from broker– Redeem tickets with node managers to acquire resources– If resources can be acquired, start service

Obtaining a Slice

Agent

Service Manager

Broker

Obtaining a Slice

Agent

Service Manager

BrokerResource Monitor

Obtaining a Slice

Agent

Service Manager

BrokerResource Monitor

Obtaining a Slice

Agent

Service Manager

BrokerResource Monitor

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

Resource Monitor

Resource Monitor

Obtaining a Slice

Agent

Service Manager

Broker

ticket

Resource Monitor

Resource Monitor

ticket

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

ticket

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

ticket

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

ticket

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

ticket

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

ticket

ticketNode Manager

Node Manager

Obtaining a Slice

Agent

Service Manager

Broker

ticket

Obtaining a Slice

Agent

Service Manager

Broker

ticket

PlanetLab Today

www.planet-lab.org

PlanetLab Today

• Global distributed systems infrastructure– platform for long-running services– testbed for network experiments

• 583 nodes around the world– 30 countries– 250+ institutions (universities, research labs, gov’t)

• Standard PC servers– 150–200 users per server– 30–40 active per hour, 5–10 at any given time– memory, CPU both heavily over-utilised

Node Software

• Linux Fedora Core 2– kernel being upgraded to FC4– always up-to-date with security-related patches

• VServer patches provide security– each user gets own VM (‘slice’)– limited root capabilities

• CKRM/VServer patches provide resource mgmt– proportional share CPU scheduling– hierarchical token bucket controls network Tx bandwidth– physical memory limits– disk quotas

Issues

• Multiple VM Types– Linux vservers, Xen domains

• Federation– EU, Japan, China

• Resource Allocation– Policy, markets

• Infrastructure Services– Delegation

Need to define the PlanetLab Architecture

Key Architectural Ideas

• Distributed virtualization– slice = set of virtual machines

• Unbundled management– infrastructure services run in their own slice

• Chain of responsibility– account for behavior of third-party software– manage trust relationships

N x N

Trust Relationships

PrincetonBerkeleyWashingtonMITBrownCMUNYUETHHarvardHP LabsIntelNEC LabsPurdueUCSDSICSCambridgeCornell…

princeton_codeennyu_dcornell_beehiveatt_mcashcmu_esmharvard_icehplabs_donutlabidsl_pseprirb_phiparis6_landmarksmit_dhtmcgill_cardhuji_enderarizona_storkucb_bambooucsd_shareumd_scriptroute…

TrustedIntermediary

(PLC)

Principals

• Node Owners– host one or more nodes (retain ultimate control)– selects an MA and approves of one or more SAs

• Service Providers (Developers)– implements and deploys network services– responsible for the service’s behavior

• Management Authority (MA)– installs an maintains software on nodes– creates VMs and monitors their behavior

• Slice Authority (SA)– registers service providers– creates slices and binds them to responsible provider

Trust Relationships(1) Owner trusts MA to map network

activity to responsible sliceMA

Owner Provider

SA

(2) Owner trusts SA to map slice to responsible providers

1

2

5

6

(3) Provider trusts SA to create VMs on its behalf

3

(4) Provider trusts MA to provide working VMs & not falsely accuse it

4

(5) SA trusts provider to deploy responsible services

(6) MA trusts owner to keep nodes physically secure

Architectural Elements

MA

NM +VMM

nodedatabase

NodeOwner

OwnerVM

SCS

SAslicedatabase

VM ServiceProvider

Narrow Waist

• Name space for slices< slice_authority, slice_name >

• Node Manager Interfacerspec = < vm_type = linux_vserver,

cpu_share = 32,

mem_limit - 128MB,

disk_quota = 5GB,

base_rate = 1Kbps,

burst_rate = 100Mbps,

sustained_rate = 1.5Mbps >

Node Boot/Install ProcessNode PLC Boot Server

1. Boots from BootCD (Linux loaded)

2. Hardware initialized

3. Read network config . from floppy

7. Node key read into memory from floppy

4. Contact PLC (MA)

6. Execute boot mgr

Boot Manager

8. Invoke Boot API

10. State = “install”, run installer

11. Update node state via Boot API

13. Chain-boot node (no restart)

14. Node booted

9. Verify node key, send current node state

12. Verify node key, change state to “boot”

5. Send boot manager

PlanetFlow

• Logs every outbound IP flow on every node– accesses ulogd via Proper– retrieves packet headers, timestamps, context ids (batched)– used to audit traffic

• Aggregated and archived at PLC

Chain of ResponsibilityJoin Request PI submits Consortium paperwork and requests to join

PI Activated PLC verifies PI, activates account, enables site (logged)

User Activated Users create accounts with keys, PI activates accounts (logged)

Nodes Added to Slices

Users add nodes to their slice (logged)

Slice Traffic Logged

Experiments run on nodes and generate traffic (logged by Netflow)

Traffic Logs Centrally Stored

PLC periodically pulls traffic logs from nodes

Slice Created PI creates slice and assigns users to it (logged)

Network Activity Slice Responsible Users & PI

Slice Creation

PLC(SA)

VMM

NM VM

PI SliceCreate( ) SliceUsersAdd( )

User SliceNodesAdd( ) SliceAttributeSet( ) SliceInstantiate( )

SliceGetAll( )

slices.xml VM VM…

.

.

.

.

.

.

Slice Creation

PLC(SA)

VMM

NM VM

PI SliceCreate( ) SliceUsersAdd( )

User SliceAttributeSet( ) SliceGetTicket( )

VM VM…

.

.

.

.

.

.

(distribute ticket to slice creation service)

SliverCreate(ticket)

Brokerage Service

PLC(SA)

VMM

NM VM

PI SliceCreate( ) SliceUsersAdd( )

Broker SliceAttributeSet( ) SliceGetTicket( )

VM VM…

.

.

.

.

.

.

(distribute ticket to brokerage service)

rcap = PoolCreate(ticket)

Brokerage Service (cont)

PLC(SA)

VMM

NM VM VM VM…

.

.

.

.

.

.

(broker contacts relevant nodes)

PoolSplit(rcap, slice, rspec)

VM

User BuyResources( ) Broker

VIRTUAL MACHINES

PlanetLab Virtual Machines: VServers

• Extend the idea of chroot(2)– New vserver created by system call– Descendent processes inherit vserver– Unique filesystem, SYSV IPC, UID/GID space– Limited root privilege

• Can’t control host node

– Irreversible

Scalability

• Reduce disk footprint using copy-on-write– Immutable flag provides file-level CoW– Vservers share 508MB basic filesystem

• Each additional vserver takes 29MB

• Increase limits on kernel resources (e.g., file descriptors)– Is the kernel designed to handle this? (inefficient data

structures?)

Protected Raw Sockets

• Services may need low-level network access– Cannot allow them access to other services’ packets

• Provide “protected” raw sockets– TCP/UDP bound to local port– Incoming packets delivered only to service with corresponding port

registered– Outgoing packets scanned to prevent spoofing

• ICMP also supported– 16-bit identifier placed in ICMP header

Resource Limits

• Node-wide cap on outgoing network bandwidth– Protect the world from PlanetLab services

• Isolation between vservers: two approaches– Fairness: each of N vservers gets 1/N of the resources during

contention– Guarantees: each slice reserves certain amount of resources (e.g.,

1Mbps bandwidth, 10Mcps CPU)• Left-over resources distributed fairly

Linux and CPU Resource Management

• The scheduler in Linux provides fairness by process, not by vserver– Vserver with many processes hogs CPU

• No current way for scheduler to provide guaranteed slices of CPU time

MANAGEMENT SERVICES

PlanetLab Network Management

1. PlanetLab Nodes boot a small Linux OS from CD, run on RAM disk

2. Contacts a bootserver3. Bootserver sends a (signed) startup script

• Boot normally or• Write new filesystem or• Start sshd for remote PlanetLab Admin login

• Nodes can be remotely power-cycled

Dynamic Slice Creation

1. Node Manager verifies tickets from service manager

2. Creates a new vserver

3. Creates an account on the node and on the vserver

User Logs in to PlanetLab Node

• /bin/vsh immediately:1. Switches to the account’s associated vserver

2. Chroot()s to the associated root directory

3. Relinquishes true root privileges

4. Switch UID/GID to account on vserver

– Transition to vserver is transparent: it appears the user just logged into the PlanetLab node directly