CS252 Graduate Computer Architecture Lecture 15 Multiprocessor Networks (con’t) March 15 th, 2010...
-
date post
21-Dec-2015 -
Category
Documents
-
view
215 -
download
1
Transcript of CS252 Graduate Computer Architecture Lecture 15 Multiprocessor Networks (con’t) March 15 th, 2010...
CS252Graduate Computer Architecture
Lecture 15
Multiprocessor Networks (con’t)March 15th, 2010
John Kubiatowicz
Electrical Engineering and Computer Sciences
University of California, Berkeley
http://www.eecs.berkeley.edu/~kubitron/cs252
3/15/2010 cs252-S10, Lecture 15 2
What characterizes a network?
• Topology (what)– physical interconnection structure of the network graph– direct: node connected to every switch– indirect: nodes connected to specific subset of switches
• Routing Algorithm (which)– restricts the set of paths that msgs may follow– many algorithms with different properties
» deadlock avoidance?
• Switching Strategy (how)– how data in a msg traverses a route– circuit switching vs. packet switching
• Flow Control Mechanism (when)– when a msg or portions of it traverse a route– what happens when traffic is encountered?
3/15/2010 cs252-S10, Lecture 15 3
Formalism
• network is a graph V = {switches and nodes} connected by communication channels C V V
• Channel has width w and signaling rate f = – channel bandwidth b = wf
– phit (physical unit) data transferred per cycle
– flit - basic unit of flow-control
• Number of input (output) channels is switch degree
• Sequence of switches and links followed by a message is a route
• Think streets and intersections
3/15/2010 cs252-S10, Lecture 15 4
Topological Properties
• Routing Distance - number of links on route
• Diameter - maximum routing distance
• Average Distance
• A network is partitioned by a set of links if their removal disconnects the graph
3/15/2010 cs252-S10, Lecture 15 5
Interconnection Topologies
• Class of networks scaling with N• Logical Properties:
– distance, degree
• Physical properties– length, width
• Fully connected network– diameter = 1– degree = N– cost?
» bus => O(N), but BW is O(1) - actually worse» crossbar => O(N2) for BW O(N)
• VLSI technology determines switch degree
3/15/2010 cs252-S10, Lecture 15 6
Example: Linear Arrays and Rings
• Linear Array– Diameter?– Average Distance?– Bisection bandwidth?– Route A -> B given by relative address R = B-A
• Torus?• Examples: FDDI, SCI, FiberChannel Arbitrated Loop, KSR1
Linear Array
Torus
Torus arranged to use short wires
3/15/2010 cs252-S10, Lecture 15 7
Example: Multidimensional Meshes and Tori
• n-dimensional array– N = kn-1 X ...X kO nodes
– described by n-vector of coordinates (in-1, ..., iO)
• n-dimensional k-ary mesh: N = kn
– k = nN
– described by n-vector of radix k coordinate
• n-dimensional k-ary torus (or k-ary n-cube)?
2D Grid 3D Cube2D Torus
3/15/2010 cs252-S10, Lecture 15 8
On Chip: Embeddings in two dimensions
• Embed multiple logical dimension in one physical dimension using long wires
• When embedding higher-dimension in lower one, either some wires longer than others, or all wires long
6 x 3 x 2
3/15/2010 cs252-S10, Lecture 15 9
Trees
• Diameter and ave distance logarithmic– k-ary tree, height n = logk N– address specified n-vector of radix k coordinates describing path down from
root• Fixed degree• Route up to common ancestor and down
– R = B xor A– let i be position of most significant 1 in R, route up i+1 levels– down in direction given by low i+1 bits of B
• H-tree space is O(N) with O(N) long wires• Bisection BW?
3/15/2010 cs252-S10, Lecture 15 10
Fat-Trees
• Fatter links (really more of them) as you go up, so bisection BW scales with N
Fat Tree
3/15/2010 cs252-S10, Lecture 15 11
Butterflies
• Tree with lots of roots! • N log N (actually N/2 x logN)• Exactly one route from any source to any dest• R = A xor B, at level i use ‘straight’ edge if ri=0, otherwise
cross edge• Bisection N/2 vs N (n-1)/n
(for n-cube)
0
1
2
3
4
16 node butterfly
0 1 0 1
0 1 0 1
0 1
building block
3/15/2010 cs252-S10, Lecture 15 12
k-ary n-cubes vs k-ary n-flies• degree n vs degree k
• N switches vs N log N switches
• diminishing BW per node vs constant
• requires locality vs little benefit to locality
• Can you route all permutations?
3/15/2010 cs252-S10, Lecture 15 13
Benes network and Fat Tree
• Back-to-back butterfly can route all permutations
• What if you just pick a random mid point?
16-node Benes Network (Unidirectional)
16-node 2-ary Fat-Tree (Bidirectional)
3/15/2010 cs252-S10, Lecture 15 14
Hypercubes• Also called binary n-cubes. # of nodes = N = 2n.
• O(logN) Hops
• Good bisection BW
• Complexity– Out degree is n = logN
correct dimensions in order
– with random comm. 2 ports per processor
0-D 1-D 2-D 3-D 4-D 5-D !
3/15/2010 cs252-S10, Lecture 15 15
Some Properties • Routing
– relative distance: R = (b n-1 - a n-1, ... , b0 - a0 )
– traverse ri = b i - a i hops in each dimension
– dimension-order routing? Adaptive routing?
• Average Distance Wire Length?– n x 2k/3 for mesh
– nk/2 for cube
• Degree?
• Bisection bandwidth? Partitioning?– k n-1 bidirectional links
• Physical layout?– 2D in O(N) space Short wires
– higher dimension?
3/15/2010 cs252-S10, Lecture 15 16
The Routing problem: Local decisions
• Routing at each hop: Pick next output port!
Cross-bar
InputBuffer
Control
OutputPorts
Input Receiver Transmiter
Ports
Routing, Scheduling
OutputBuffer
3/15/2010 cs252-S10, Lecture 15 17
How do you build a crossbar?
Io
I1
I2
I3
Io I1 I2 I3
O0
Oi
O2
O3
RAMphase
O0
Oi
O2
O3
DoutDin
Io
I1
I2
I3
addr
3/15/2010 cs252-S10, Lecture 15 18
Input buffered switch
• Independent routing logic per input– FSM
• Scheduler logic arbitrates each output– priority, FIFO, random
• Head-of-line blocking problem– Message at head of queue blocks messages behind it
Cross-bar
OutputPorts
Input Ports
Scheduling
R0
R1
R2
R3
3/15/2010 cs252-S10, Lecture 15 19
Output Buffered Switch
• How would you build a shared pool?
Control
OutputPorts
Input Ports
OutputPorts
OutputPorts
OutputPorts
R0
R1
R2
R3
3/15/2010 cs252-S10, Lecture 15 20
Properties of Routing Algorithms• Routing algorithm:
– R: N x N -> C, which at each switch maps the destination node nd to the next channel on the route
– which of the possible paths are used as routes?– how is the next hop determined?
» arithmetic» source-based port select» table driven» general computation
• Deterministic– route determined by (source, dest), not intermediate state (i.e. traffic)
• Adaptive– route influenced by traffic along the way
• Minimal– only selects shortest paths
• Deadlock free– no traffic pattern can lead to a situation where packets are deadlocked
and never move forward
3/15/2010 cs252-S10, Lecture 15 21
Example: Simple Routing Mechanism• need to select output port for each input packet
– in a few cycles
• Simple arithmetic in regular topologies– ex: x, y routing in a grid
» west (-x) x < 0
» east (+x) x > 0
» south (-y) x = 0, y < 0
» north (+y) x = 0, y > 0
» processor x = 0, y = 0
• Reduce relative address of each dimension in order– Dimension-order routing in k-ary d-cubes
– e-cube routing in n-cube
3/15/2010 cs252-S10, Lecture 15 22
Administrative• Exam: This Wednesday (3/17)
Location: 310 SodaTIME: 6:00-9:00
– This info is on the Lecture page (has been)
– Get on 8 ½ by 11 sheet of notes (both sides)
– Meet at LaVal’s afterwards for Pizza and Beverages
• Assume that major papers we have discussed may show up on exam
3/15/2010 cs252-S10, Lecture 15 23
Communication Performance
• Typical Packet includes data + encapsulation bytes– Unfragmented packet size S = Sdata+Sencapsulation
• Routing Time:– Time(S)s-d = overhead + routing delay + channel
occupancy + contention delay
– Channel occupancy = S/b = (Sdata+ Sencapsulation)/b
– Routing delay in cycles (» Time to get head of packet to next hop
– Contention?
Ro
uting
and
Co
ntrol H
eader
Data
Payload
Erro
rC
ode
Trailer
digitalsymbol
Sequence of symbols transmitted over a channel
3/15/2010 cs252-S10, Lecture 15 24
Store&Forward vs Cut-Through Routing
Time: h(S/b + ) vs S/b + h OR(cycles): h(S/w + ) vs S/w + h
• what if message is fragmented?• wormhole vs virtual cut-through
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1 0
23 1
023
3 1 0
2 1 0
23 1 0
0
1
2
3
23 1 0Time
Store & Forward Routing Cut-Through Routing
Source Dest Dest
3/15/2010 cs252-S10, Lecture 15 25
Contention
• Two packets trying to use the same link at same time– limited buffering
– drop?
• Most parallel mach. networks block in place– link-level flow control
– tree saturation
• Closed system - offered load depends on delivered– Source Squelching
3/15/2010 cs252-S10, Lecture 15 26
Bandwidth• What affects local bandwidth?
– packet density: b x Sdata/S
– routing delay: b x Sdata /(S + w)
– contention» endpoints
» within the network
• Aggregate bandwidth– bisection bandwidth
» sum of bandwidth of smallest set of links that partition the network
– total bandwidth of all the channels: Cb
– suppose N hosts issue packet every M cycles with ave dist » each msg occupies h channels for l = S/w cycles each
» C/N channels available per node
» link utilization for store-and-forward: = (hl/M channel cycles/node)/(C/N) = Nhl/MC < 1!
» link utilization for wormhole routing?
3/15/2010 cs252-S10, Lecture 15 27
Saturation
0
10
20
30
40
50
60
70
80
0 0.2 0.4 0.6 0.8 1
Delivered Bandwidth
Lat
ency
Saturation
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0 0.2 0.4 0.6 0.8 1 1.2
Offered BandwidthD
eliv
ered
Ban
dw
idth
Saturation
3/15/2010 cs252-S10, Lecture 15 28
How Many Dimensions?• n = 2 or n = 3
– Short wires, easy to build
– Many hops, low bisection bandwidth
– Requires traffic locality
• n >= 4– Harder to build, more wires, longer average length
– Fewer hops, better bisection bandwidth
– Can handle non-local traffic
• k-ary n-cubes provide a consistent framework for comparison
– N = kn
– scale dimension (n) or nodes per dimension (k)
– assume cut-through
3/15/2010 cs252-S10, Lecture 15 29
Traditional Scaling: Latency scaling with N
• Assumes equal channel width– independent of node count or dimension
– dominated by average distance
0
50
100
150
200
250
0 2000 4000 6000 8000 10000
Machine Size (N)
Ave L
ate
ncy
T(S
=140)
0
20
40
60
80
100
120
140
0 2000 4000 6000 8000 10000
Machine Size (N)
Ave L
ate
ncy
T(S
=40)
n=2
n=3
n=4
k=2
S/w
3/15/2010 cs252-S10, Lecture 15 30
Average Distance
• but, equal channel width is not equal cost!
• Higher dimension => more channels
0
10
20
30
40
50
60
70
80
90
100
0 5 10 15 20 25
Dimension
Ave D
ista
nce
256
1024
16384
1048576
ave dist = n(k-1)/2
3/15/2010 cs252-S10, Lecture 15 31
Dally Paper: In the 3D world• For N nodes, bisection area is O(N2/3 )
• For large N, bisection bandwidth is limited to O(N2/3 )– Bill Dally, IEEE TPDS, [Dal90a]
– For fixed bisection bandwidth, low-dimensional k-ary n-cubes are better (otherwise higher is better)
– i.e., a few short fat wires are better than many long thin wires
– What about many long fat wires?
3/15/2010 cs252-S10, Lecture 15 32
Dally paper (con’t)• Equal Bisection,W=1 for hypercube W= ½k
• Three wire models:– Constant delay, independent of length
– Logarithmic delay with length (exponential driver tree)
– Linear delay (speed of light/optimal repeaters)
Logarithmic Delay Linear Delay
3/15/2010 cs252-S10, Lecture 15 33
Equal cost in k-ary n-cubes• Equal number of nodes?• Equal number of pins/wires?• Equal bisection bandwidth?• Equal area?• Equal wire length?
What do we know?• switch degree: n diameter = n(k-1)• total links = Nn• pins per node = 2wn• bisection = kn-1 = N/k links in each directions• 2Nw/k wires cross the middle
3/15/2010 cs252-S10, Lecture 15 34
Latency for Equal Width Channels
• total links(N) = Nn
0
50
100
150
200
250
0 5 10 15 20 25
Dimension
Average L
ate
ncy (S =
40, D
= 2
)256
1024
16384
1048576
3/15/2010 cs252-S10, Lecture 15 35
Latency with Equal Pin Count
• Baseline n=2, has w = 32 (128 wires per node)
• fix 2nw pins => w(n) = 64/n
• distance up with n, but channel time down
0
50
100
150
200
250
300
0 5 10 15 20 25
Dimension (n)
Ave
Lat
ency
T(S
=40B
)
256 nodes
1024 nodes
16 k nodes
1M nodes
0
50
100
150
200
250
300
0 5 10 15 20 25
Dimension (n)
Ave
Lat
ency
T(S
= 1
40 B
)
256 nodes
1024 nodes
16 k nodes
1M nodes
3/15/2010 cs252-S10, Lecture 15 36
Latency with Equal Bisection Width
• N-node hypercube has N bisection links
• 2d torus has 2N 1/2
• Fixed bisection w(n) = N 1/n / 2 = k/2
• 1 M nodes, n=2 has w=512!0
100
200
300
400
500
600
700
800
900
1000
0 5 10 15 20 25
Dimension (n)
Ave L
ate
ncy T
(S=40)
256 nodes
1024 nodes
16 k nodes
1M nodes
3/15/2010 cs252-S10, Lecture 15 37
Larger Routing Delay (w/ equal pin)
• Dally’s conclusions strongly influenced by assumption of small routing delay
– Here, Routing delay =20
0
100
200
300
400
500
600
700
800
900
1000
0 5 10 15 20 25
Dimension (n)
Ave L
ate
ncy
T(S
= 1
40 B
)
256 nodes
1024 nodes
16 k nodes
1M nodes
3/15/2010 cs252-S10, Lecture 15 38
Saturation
• Fatter links shorten queuing delays
0
50
100
150
200
250
0 0.2 0.4 0.6 0.8 1
Ave Channel Utilization
Late
ncy
S/w=40
S/w=16
S/w=8
S/w=4
3/15/2010 cs252-S10, Lecture 15 39
• Problem: Low-dimensional networks have high k– Consequence: may have to travel many hops in single dimension– Routing latency can dominate long-distance traffic patterns
• Solution: Provide one or more “express” links
– Like express trains, express elevators, etc» Delay linear with distance, lower constant» Closer to “speed of light” in medium» Lower power, since no router cost
– “Express Cubes: Improving performance of k-ary n-cube interconnection networks,” Bill Dally 1991
• Another Idea: route with pass transistors through links
Reducing routing delay: Express Cubes
3/15/2010 cs252-S10, Lecture 15 40
• Problem: A blocked message can prevent others from using physical channels:
• Idea: add channels!– provide multiple “virtual channels” to break the dependence cycle
– good for BW too!
– Do not need to add links, or xbar, only buffer resources
Reducing Contention with Virtual Channels
OutputPorts
Input Ports
Cross-Bar
3/15/2010 cs252-S10, Lecture 15 41
Paper Discussion: Bill Dally“Virtual Channel Flow Control”
• Basic Idea: Use of virtual channels to reduce contention– Provided a model of k-ary, n-flies
– Also provided simulation
• Tradeoff: Better to split buffers into virtual channels– Example (constant total storage for 2-ary 8-fly):
3/15/2010 cs252-S10, Lecture 15 42
When are virtual channels allocated?
• Two separate processes:– Virtual channel allocation– Switch/connection allocation
• Virtual Channel Allocation– Choose route and free output virtual channel – Really means: Source of link tracks channels at destination
• Switch Allocation– For incoming virtual channel, negotiate switch on outgoing pin
OutputPorts
Input Ports
Cross-BarHardware efficient designFor crossbar
3/15/2010 cs252-S10, Lecture 15 43
Deadlock Freedom• How can deadlock arise?
– necessary conditions:» shared resource» incrementally allocated» non-preemptible
– channel is a shared resource that is acquired incrementally» source buffer then dest. buffer» channels along a route
• How do you avoid it?– constrain how channel resources are allocated– ex: dimension order
• Important assumption: – Destination of messages must always remove messages
• How do you prove that a routing algorithm is deadlock free?
– Show that channel dependency graph has no cycles!
3/15/2010 cs252-S10, Lecture 15 44
Consider Trees
• Why is the obvious routing on X deadlock free?– butterfly?
– tree?
– fat tree?
• Any assumptions about routing mechanism? amount of buffering?
3/15/2010 cs252-S10, Lecture 15 45
Up*-Down* routing for general topology• Given any bidirectional network
• Construct a spanning tree
• Number of the nodes increasing from leaves to roots
• UP increase node numbers
• Any Source -> Dest by UP*-DOWN* route– up edges, single turn, down edges
– Proof of deadlock freedom?
• Performance?– Some numberings and routes much better than others
– interacts with topology in strange ways
3/15/2010 cs252-S10, Lecture 15 46
Turn Restrictions in X,Y
• XY routing forbids 4 of 8 turns and leaves no room for adaptive routing
• Can you allow more turns and still be deadlock free?
+Y
-Y
+X-X
3/15/2010 cs252-S10, Lecture 15 47
Minimal turn restrictions in 2D
West-first
north-last negative first
-x +x
+y
-y
3/15/2010 cs252-S10, Lecture 15 48
Example legal west-first routes
• Can route around failures or congestion
• Can combine turn restrictions with virtual channels
3/15/2010 cs252-S10, Lecture 15 49
General Proof Technique• resources are logically associated with channels
• messages introduce dependences between resources as they move forward
• need to articulate the possible dependences that can arise between channels
• show that there are no cycles in Channel Dependence Graph
– find a numbering of channel resources such that every legal route follows a monotonic sequence no traffic pattern can lead to deadlock
• network need not be acyclic, just channel dependence graph
3/15/2010 cs252-S10, Lecture 15 50
Example: k-ary 2D array• Thm: Dimension-ordered (x,y) routing
is deadlock free
• Numbering– +x channel (i,y) -> (i+1,y) gets i
– similarly for -x with 0 as most positive edge
– +y channel (x,j) -> (x,j+1) gets N+j
– similary for -y channels
• any routing sequence: x direction, turn, y direction is increasing
• Generalization: – “e-cube routing” on 3-D: X then Y then Z
1 2 3
01200 01 02 03
10 11 12 13
20 21 22 23
30 31 32 33
17
18
1916
17
18
3/15/2010 cs252-S10, Lecture 15 51
Channel Dependence Graph
1 2 3
01200 01 02 03
10 11 12 13
20 21 22 23
30 31 32 33
17
18
1916
17
18
1 2 3
012
1718 1718 1718 1718
1 2 3
012
1817 1817 1817 1817
1 2 3
012
1916 1916 1916 1916
1 2 3
012
3/15/2010 cs252-S10, Lecture 15 52
More examples:• What about wormhole routing on a ring?
• Or: Unidirectional Torus of higher dimension?
012
3
45
6
7
3/15/2010 cs252-S10, Lecture 15 53
Breaking deadlock with virtual channels
• Basic idea: Use virtual channels to break cycles– Whenever wrap around, switch to different set of channels
– Can produce numbering that avoids deadlock
Packet switchesfrom lo to hi channel
3/15/2010 cs252-S10, Lecture 15 54
General Adaptive Routing• R: C x N x -> C• Essential for fault tolerance
– at least multipath
• Can improve utilization of the network• Simple deterministic algorithms easily run into bad
permutations
• fully/partially adaptive, minimal/non-minimal• can introduce complexity or anomalies • little adaptation goes a long way!
3/15/2010 cs252-S10, Lecture 15 55
Paper Discusion: Linder and Harden “An Adaptive and Fault Tolerant Wormhole”
• General virtual-channel scheme for k-ary n-cubes– With wrap-around paths
• Properties of result for uni-directional k-ary n-cube:– 1 virtual interconnection network
– n+1 levels
• Properties of result for bi-directional k-ary n-cube:– 2n-1 virtual interconnection networks
– n+1 levels per network
3/15/2010 cs252-S10, Lecture 15 56
Example: Unidirectional 4-ary 2-cube
Physical Network• Wrap-around channels
necessary but cancause deadlock
Virtual Network• Use VCs to avoid deadlock• 1 level for each wrap-around
3/15/2010 cs252-S10, Lecture 15 57
Bi-directional 4-ary 2-cube: 2 virtual networks
Virtual Network 1 Virtual Network 2
3/15/2010 cs252-S10, Lecture 15 58
Use of virtual channels for adaptation• Want to route around hotspots/faults while avoiding deadlock• Linder and Harden, 1991
– General technique for k-ary n-cubes» Requires: 2n-1 virtual channels/lane!!!
• Alternative: Planar adaptive routing– Chien and Kim, 1995– Divide dimensions into “planes”,
» i.e. in 3-cube, use X-Y and Y-Z
– Route planes adaptively in order: first X-Y, then Y-Z» Never go back to plane once have left it» Can’t leave plane until have routed lowest coordinate
– Use Linder-Harden technique for series of 2-dim planes» Now, need only 3 number of planes virtual channels
• Alternative: two phase routing– Provide set of virtual channels that can be used arbitrarily for routing– When blocked, use unrelated virtual channels for dimension-order
(deterministic) routing– Never progress from deterministic routing back to adaptive routing
3/15/2010 cs252-S10, Lecture 15 59
Summary #1• Network Topologies:
• Fair metrics of comparison– Equal cost: area, bisection bandwidth, etc
Topology Degree Diameter Ave Dist Bisection D (D ave) @ P=1024
1D Array 2 N-1 N / 3 1 huge
1D Ring 2 N/2 N/4 2
2D Mesh 4 2 (N1/2 - 1) 2/3 N1/2 N1/2 63 (21)
2D Torus 4 N1/2 1/2 N1/2 2N1/2 32 (16)
k-ary n-cube 2n nk/2 nk/4 nk/4 15 (7.5) @n=3
Hypercube n =log N n n/2 N/2 10 (5)
3/15/2010 cs252-S10, Lecture 15 60
Summary #2• Routing Algorithms restrict the set of routes within
the topology– simple mechanism selects turn at each hop
– arithmetic, selection, lookup
• Virtual Channels – Adds complexity to router
– Can be used for performance
– Can be used for deadlock avoidance
• Deadlock-free if channel dependence graph is acyclic
– limit turns to eliminate dependences
– add separate channel resources to break dependences
– combination of topology, algorithm, and switch design
• Deterministic vs adaptive routing