Subexponential Algorithms for Unique Games and Related Problems Barriers II Workshop, Princeton, August 2010 David Steurer MSR New England Sanjeev Arora.

Subexponential Algorithms for Unique Games and Related Problems Barriers II Workshop, Princeton, August 2010 David Steurer MSR New England Sanjeev Arora Princeton University & CCI Boaz Barak Princeton & MSR New England U

Introduction Small-Set Expansion Unique Games

U NIQUE G AMES Input:list of constraints of form x i – x j = c ij mod k Goal:satisfy as many constraints as possible Input:U NIQUE G AMES instance with k << log n (say) Goal: Distinguish two cases YES: more than 1 - ² of constraints satisfiable NO: less than ² of constraints satisfiable Khot’s Unique Games Conjecture (UGC) For every ² > 0, the following is NP-hard: UG( ² )

Implications of UGC For many basic optimization problems, it is NP-hard to beat current algorithms (based on simple LP or SDP relaxations) Examples: V ERTEX C OVER [Khot Regev’03], M AX C UT [KhotKindlerMosselO’Donnell’04, MosselO’DonnellOleszkiewicz’05], any M AX C SP [Raghavendra’08], …

Unique Games Barrier Example: ( ® GW + ² )-approximation for M AX C UT at least as hard as UG( ² ’) U NIQUE G AMES is common barrier for improving current algorithms of many basic problems Reductions show that beating current algorithms for these problems is harder than U NIQUE G AMES ® GW = 0.878… Goemans–Williamson bound for Max Cut Implications of UGC For many basic optimization problems, it is NP-hard to beat current algorithms (based on simple LP or SDP relaxations) Examples: V ERTEX C OVER [KR’03], M AX C UT [KKMO,’04 MOO’05], any M AX C SP [Raghavendra’08], …

Consequences for UGC (*) Analog of UGC with subconstant ² (say ² = 1/log log n) is false (contrast: subconstant hardness for L ABEL C OVER [Moshkovitz-Raz’08]) Subexponential Algorithm for Unique Games In particular: UG( ² 3 ) has exp(n ² )-time algorithm Given a U NIQUE G AMES instance with alphabet size k such that 1 - ² of constraints are satisfiable, can satisfy 1 - √ ² / ¯ 3 of constraints in time exp(k n ¯ ) NP-hardness reduction for UG( ² ) requires blow-up n poly(1/ ² )  rules out certain classes of reductions for proving UGC (*) assuming 3 S AT does not have subexponential algorithms

poly(n)exp(n) Concrete Complexity Landscape 2-S AT M AX 3-S AT (7/8) M AX C UT ( ® GW ) * assuming Exponential Time Hypothesis [Impagliazzo-Paturi-Zane’01] ( 3-S AT has no exp(o(n)) algorithm ) 3-S AT (*) Factoring Graph Isomorphism exp(n 1/2 )exp(n 1/3 )exp(n ² ) UG( ² 3 ) M AX 3-S AT (7/8+ ² ) L ABEL C OVER ( ² ) [Moshkovitz-Raz’08 + Håstad’97] If UGC true, U NIQUE G AMES is first CSP with intermediate complexity M AX C UT ( ® GW + ² )? UGC-based hardness does not rule out subexponential algorithms,  Possibility: exp(n ² )-time algorithm for M AX C UT ( ® GW + ² ) U NIQUE G AMES much easier than L ABEL C OVER Implications of U NIQUE G AMES algorithm (*)

d-regular graph G d vertex set S Graph Expansion expansion(S) = # edges leaving S d |S| volume(S ) = |S| |V|

S expansion(S) = # edges leaving S d |S| Graph Expansion volume(S ) = |S| |V| S MALL -S ET E XPANSION Goal:find S with volume(S) < ± so as to minimize expansion(S) Input:d-regular graph G, parameter ± > 0 Important concept in many contexts: derandomization, network routing, coding theory, Markov chains, differential geometry, group theory close connection to U NIQUE G AMES [Raghavendra-S.’10]

S expansion(S) = # edges leaving S d |S| Graph Expansion volume(S ) = |S| |V| Important concept in many contexts: derandomization, network routing, coding theory, Markov chains, differential geometry, group theory Subexponential Algorithm for S MALL -S ET E XPANSION If there exists S with volume(S) < ± and expansion(S) < ², we can find S’ with volume(S’) < 2 ± and expansion(S’) < √ ² / ¯ in time exp(n ¯ / ± )

Subexponential Algorithm for S MALL -S ET E XPANSION If there exists S with volume(S) < ± and expansion(S) < ², we can find S’ with volume(S’) < 2 ± and expansion(S’) < √ ² / ¯ in time exp(n ¯ / ± )

1.few large eigenvalues 2.many large eigenvalues Distinguish two cases: large eigenvalues ¸ i > 1 - ´ Eigenvalues of the random walk matrix G: 1 = ¸ 1 ¸ … ¸ ¸ m ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 (pseudorandom graph) (structured graph?) Subexponential Algorithm for S MALL -S ET E XPANSION If there exists S with volume(S) < ± and expansion(S) < ², we can find S’ with volume(S’) < 2 ± and expansion(S’) < √ ² / ¯ in time exp(n ¯ / ± ) ´ À ² (best: ´ = 100 ², simpler: ´ = ² 0.75 )

1 - ´ Eigenvalues of the random walk matrix G: 1 = ¸ 1 ¸ … ¸ ¸ m ¸ Subexponential Algorithm for S MALL -S ET E XPANSION If there exists S with volume(S) < ± and expansion(S) < ², we can find S’ with volume(S’) < 2 ± and expansion(S’) < √ ² / ¯ in time exp(n ¯ / ± ) ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 large eigenvalues ¸ i > 1 - ´

Case 1: Few large eigenvalues: (inspired by [Kolla–Tulsiani ’07] and [Kolla’10]) 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Expander Mixing Lemma: indicator vector of S lives almost completely in span of top m eigenvectors Eigenvalues of the random walk matrix G:  can find set S’ close to S in time exp(m) Enumerate this space in time exp(m) Case 2: Many large eigenvalues (m > n ¯ / ± )  can find small non-expanding set S’ around that vertex Will show: 9 vertex whose neighborhoods grow very slowly Subexponential Algorithm for S MALL -S ET E XPANSION If there exists S with volume(S) < ± and expansion(S) < ², we can find S’ with volume(S’) < 2 ± and expansion(S’) < √ ² / ¯ in time exp(n ¯ / ± )

Case 1: Few large eigenvalues: 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G:

Case 1: Few large eigenvalues Subspace enumeration (inspired by [Kolla–Tulsiani ’07] and [Kolla’10]) Eigenvalues of the random walk matrix G: Suffices to show: indicator vector of S is ² / ´ -close to U |S ¢ S’| < ² / ´ |S [ S’| For every set S with expansion(S) < ², can find S’ that is ² / ´ -close to S in time exp(m) Algorithm: Let U be span of top-m eigenvectors For every vector u in ² -net of unit ball of U, output all level sets of u U 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1

Case 1: Few large eigenvalues Subspace enumeration (inspired by [Kolla–Tulsiani ’07] and [Kolla’10]) Eigenvalues of the random walk matrix G: Suffices to show: indicator vector of S is ² / ´ -close to U (generalization of “easy direction” of Cheeger’s inequality) h x, G x i > 1 - ² because expansion(S) < ² x = normalized indicator vector of S 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 For every set S with expansion(S) < ², can find S’ that is ² / ´ -close to S in time exp(m)

Case 1: Few large eigenvalues Subspace enumeration (inspired by [Kolla–Tulsiani ’07] and [Kolla’10]) Eigenvalues of the random walk matrix G: (generalization of “easy direction” of Cheeger’s inequality) h x, G x i = h u, G u i + h w, G w i < h u,u i + (1 - ´ ) h w,w i = 1 - ´ h w,w i Suppose x = u + w for u in U and w orthogonal to U h x, G x i > 1 - ² because expansion(S) < ² x = normalized indicator vector of S 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Suffices to show: indicator vector of S is ² / ´ -close to U For every set S with expansion(S) < ², can find S’ that is ² / ´ -close to S in time exp(m)

Eigenvalues of the random walk matrix G: 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1

Case 2: Many large eigenvalues (m > n ¯ / ± ) Eigenvalues of the random walk matrix G: 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1

If m > 1, then 9 S with volume(S) < ½ and expansion(S) < √ ´ and we can find S in poly(n)-time. Compare: “hard direction” of Cheeger’s inequality Case 2: Many large eigenvalues (m > n ¯ / ± ) 1 = ¸ 1 ¸ …………………… ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G: If m > n ¯ / ±, then 9 S with volume(S) < ± and expansion(S) < √ ´ / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion “higher eigenvalue Cheeger bound”

Heuristic: balls tend to be the least expanding sets in graphs How can we find small non-expanding sets? Case 2: Many large eigenvalues (m > n ¯ / ± ) 1 = ¸ 1 ¸ …………………… ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G: If m > n ¯ / ±, then 9 S with volume(S) < ± and expansion(S) < √ ´ / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion

Suffices to show: 9 vertex i such that volume( Ball(i, t) ) < ± for t = ( ¯ / ´ ) log(n) Volume growth vs. small-set expansion  volume growth < 1+( ´ / ¯ ) in intermediate step  expansion( Ball(i,s) ) < ( ´ / ¯ ) for some s < t Suppose volume( Ball(i, t) ) < ± for t = ( ¯ / ´ ) log(n) Case 2: Many large eigenvalues (m > n ¯ / ± ) 1 = ¸ 1 ¸ …………………… ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G: If m > n ¯ / ±, then 9 S with volume(S) < ± and expansion(S) < √ ´ / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion

Volume growth vs. small-set expansion How can we relate eigenvalues and volume growth? Case 2: Many large eigenvalues (m > n ¯ / ± ) 1 = ¸ 1 ¸ …………………… ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G: If m > n ¯ / ±, then 9 S with volume(S) < ± and expansion(S) < √ ´ / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion Suffices to show: 9 vertex i such that volume( Ball(i, t) ) < ± for t = ( ¯ / ´ ) log(n)

Suffices to show: 9 vertex i such that volume( Ball(i, t) ) < ± for t = ( ¯ / ´ ) log(n) Heuristic: collision probability ¼ 1/|support| Collision probability decay || G t e i || 2 > 1/( ± n) collision probability of t-step random walk from i Proof follows from local variant of Cheeger’s inequality (e.g. Dimitriou–Impagliazzo’98) Case 2: Many large eigenvalues (m > n ¯ / ± ) 1 = ¸ 1 ¸ …………………… ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G: If m > n ¯ / ±, then 9 S with volume(S) < ± and expansion(S) < √ ´ / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion Volume growth vs. small-set expansion

Number of large eigenvalues vs. collision probability decay Collision probability decay vs. small-set expansion Suffices to show: 9 vertex i such that || G t e i || 2 > 1/( ± n) for t = ( ¯ / ´ ) log(n) =  i h e i, G 2t e i i = Trace(G 2t )> m ¢ (1 - ´ ) 2t > 1/ ±  i ||G t e i || 2 Case 2: Many large eigenvalues (m > n ¯ / ± ) 1 = ¸ 1 ¸ …………………… ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G: If m > n ¯ / ±, then 9 S with volume(S) < ± and expansion(S) < √ ´ / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion

Case 1: Few large eigenvalues: 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ´ ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 Eigenvalues of the random walk matrix G:  can find set S’ ² / ´ -close to S in time exp(m) Subspace enumeration: discretize span of top m eigenvectors Case 2: Many large eigenvalues (m > n ¯ / ± )  can find small non-expanding set S’ around that vertex Trace bound: 9 vertex where local random walk mixes slowly U Subexponential Algorithm for S MALL -S ET E XPANSION If there exists S with volume(S) < ± and expansion(S) < ², we can find S’ with volume(S’) < 2 ± and expansion(S’) < √ ² / ¯ in time exp(n ¯ / ± )

U NIQUE G AMES Input:list of constraints of form x i – x j = c ij mod k Goal:satisfy as many constraints as possible Constraint Graph G variable  vertex constraint  edge i j x i – x j = c ij mod k Subexponential Algorithm for Unique Games In particular: UG( ² 3 ) has exp(n ² )-time algorithm Given a U NIQUE G AMES instance with alphabet size k such that 1 - ² of constraints are satisfiable, can satisfy 1 - √ ² / ¯ 3 of constraints in time exp(k n ¯ )

can solve UG( ² 3 ) in time exp(m) Few large eigenvalues + strong L 1 bounds on top-m eigenvectors large eigenvalues Eigenvalues of the random walk matrix of constraint graph G: 1 = ¸ 1 ¸ … ¸ ¸ m > 1 - ² ¸ ¸ m+1 ¸ … ¸ ¸ n ¸ -1 [Arora–Khot–Kolla– S.–Tulsiani–Vishnoi’08] Expanding constraint graph (m=1) can solve UG( ² ) in time poly(n) [Kolla’10] U NIQUE G AMES on pseudorandom instances is easy Algorithms for special instances of Unique Games

Strategy partition general instance into pseudorandom instances by changing only a small fraction of edges [Trevisan’05] Algorithms for general instances of Unique Games general instance pseudorandom instances decomposition few constraints between parts [Arora–Impagliazzo– –Matthews–S.’10] here: Leighton–Rao decomposition tree, constant depth, using higher eigenvalue Cheeger bound here: at most n ¯ eigenvalues > 1- ² here: at most √ ² / ¯ 3 fraction

Subexponential Algorithm for Unique Games few large eigenvalues: at most n ¯ eigenvalues >1- ² Few-large-eigenvalues decomposition Every regular graph G can be partitioned into components with few large eigenvalues by removing √ ² / ¯ 3 fraction of edges Unique Games with few large eigenvalues If every component of G has few large eigenvalues, can solve UG( ² 2 ) in time exp(n ¯ )

few large eigenvalues: at most n ¯ eigenvalues >1- ² Unique Games with few large eigenvalues If every component of G has few large eigenvalues, can solve UG( ² 2 ) in time exp(n ¯ )

few large eigenvalues: at most n ¯ eigenvalues >1- ² Unique Games with few large eigenvalues If every component of G has few large eigenvalues, can solve UG( ² 2 ) in time exp(n ¯ ) label-extended graph G* i j x i – x j = c ij mod k constraint graph G cloud j cloud i (i,a) » (j,b) if a-b = c ij mod k assignment satisfying 1- ² 2 of constraints set with volume = 1/k and expansion < ² 2 Subspace enumeration: can enumerate all nonexpanding sets if G* has few large eigenvalues When does G* have here few large eigenvalues?

Unique Games with few large eigenvalues label-extended graph G* i j x i – x j = c ij mod k constraint graph G cloud j cloud i (i,a) » (j,b) if a-b = c ij mod k When does G* have here few large eigenvalues? if G is an expander [Kolla–Tulsiani’07] if G has few large eigenvalues and eigenvectors are well-spread [Kolla’10] if G has few’ large’ eigenvalues (this work, by comparing collision probabilities) If every component of G has few large eigenvalues, can solve UG( ² 2 ) in time exp(n ¯ ) few large eigenvalues: at most n ¯ eigenvalues >1- ²

Recall: (with slightly different parameters) Analysis: For every subdivision S, charge its expansion to vertices in S K If component K has many large eigenvalues, then 9 S in K with |S| < |K| 1- ¯ and expansion(S) < √ ² / ¯ and we can find S in poly(n)-time Number of large eigenvalues vs. small-set expansion Algorithm: Subdivide components until all components have few large eigenvalues  no vertex is charged more than log(1/ ¯ )/ ¯ times If vertex is charged t times, its component has size < n (1- ¯ ) t few large eigenvalues: at most n ¯ eigenvalues larger 1- ² Few-large-eigenvalues decomposition Every regular graph G can be partitioned into components with few large eigenvalues by removing √ ² / ¯ 3 fraction of edges

Open Questions Example: C-approximation for S PARSEST C UT in time exp(n 1/C ) How many large eigenvalues can a small-set expander have? Is Boolean noise graph the worst case? (polylog(n) large eigenvalues) Thank you!Questions? More Subexponential Algorithms Similar approximation for M ULTI C UT and d-T O - 1 2 -P ROVER G AMES Better approximations for M AX C UT and V ERTEX C OVER on small-set expanders What else can be done in subexponential time? Towards better-than-subexponential algorithms for U NIQUE G AMES Better approximations for M AX C UT or V ERTEX C OVER on general instances?

Subexponential Algorithms for Unique Games and Related Problems Barriers II Workshop, Princeton, August 2010 David Steurer MSR New England Sanjeev Arora.

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Subexponential Algorithms for Unique Games and Related Problems Barriers II Workshop, Princeton, August 2010 David Steurer MSR New England Sanjeev Arora.

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Presentation on theme: "Subexponential Algorithms for Unique Games and Related Problems Barriers II Workshop, Princeton, August 2010 David Steurer MSR New England Sanjeev Arora."— Presentation transcript:

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