Algorithmic minimax principle

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\DeclareMathOperator*{\Pr}{Pr} \DeclareMathOperator*{\G}{\mathbb{G}} \DeclareMathOperator*{\Odds}{Od} \DeclareMathOperator*{\E}{E} \DeclareMathOperator*{\Var}{Var} \DeclareMathOperator*{\Cov}{Cov} \DeclareMathOperator*{\K}{K} \DeclareMathOperator*{\corr}{corr} \DeclareMathOperator*{\median}{median} \DeclareMathOperator*{\maj}{maj} % ... information theory \let\H\undefined \DeclareMathOperator*{\H}{H} \DeclareMathOperator*{\I}{I} \DeclareMathOperator*{\D}{D} \DeclareMathOperator*{\KL}{KL} % .. other divergences \newcommand{\dTV}{d_{\mathrm{TV}}} \newcommand{\dHel}{d_{\mathrm{Hel}}} \newcommand{\dJS}{d_{\mathrm{JS}}} % % Polynomials \DeclareMathOperator{\He}{He} \DeclareMathOperator{\coeff}{coeff} % %%% SPECIALIZED COMPUTER SCIENCE %%% % % Complexity classes % .. keywords \newcommand{\coclass}{\mathsf{co}} \newcommand{\Prom}{\mathsf{Promise}} % .. classical \newcommand{\PTIME}{\mathsf{P}} \newcommand{\NP}{\mathsf{NP}} \newcommand{\coNP}{\coclass\NP} \newcommand{\PH}{\mathsf{PH}} 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The principle

Yao’s algorithmic minimax principle states:

For randomized algorithms, the average case is as hard as the worst case.

More precisely, whatever the best achievable worst-case performance is, there is a fixed input distribution $\CX$ over which the best possible average performance is equally bad: if $\nc{\cost}{\r{cost}}\cost_{\CA}\p{x}$ denotes the average cost that randomized algorithm $\CA$ incurs on input $x$, then

\[\al{ \min_{\CA}\ub{\max_{x \in X} \cost_\CA(x)}{worst case cost of $\CA$} = \max_{\CX \in \tri\p{X}}\ub{\min_{\CA} \E\ss{\Bx \sim \CX}\b{\cost_\CA\p{\Bx}}}{best possible average cost over $\CX$}. }\]

In addition, in the average-case setting, there is no point in having $\CA$ be randomized anymore: if the input distribution $\CX$ is fixed, we can just fix $\CA$’s internal randomness to the value that performs best on average over $\CX$.

The applications

For algorithm designers

The principle means that if we want to design a randomized algorithm that works in the worst case, it is actually fine to assume that the input $x$ is drawn from a fixed prior distribution $\CX$ and tailor the algorithm to $\CX$.

For complexity theorists

The principle shows that if there is a worst-case randomized algorithm for some task, then for any distribution $\CX$ of inputs, there is a deterministic algorithm that gets the same performance. Therefore, to prove a lower bound on randomized alorithms, it is enough to find any distribution $\CX$ which is hard for deterministic algorithms.

(Archive: previous explanation for the complexity-theoretic application)

The principle

Suppose you want to show that no good randomized algorithm/protocol/whatever exists for some problem. It is sufficent (and necessary) to show an input distribution that is hard for all deterministic algorithms/protocols/whatever.

More precisely,¹

\[\min_{\CA} \max_x \Pr_{A \sim \CA}[\text{$A$ fails on $x$}] \geq \max_{\CX} \min_{A} \Pr_{x \sim \CX}[\text{$A$ fails on $x$}].\]

Put another way, if you can find a distribution $\CX$ on which any deterministic algorithm $A$ fails on a $> \eps$ fraction of the inputs, this shows that any randomized algorithm $\CA$ must fail on some input $x$ with at least $> \eps$ probability.

The proof

Expressions with mins and maxes are confusing, so we’ll instead consider games between Algie (the algorithm) and Imperia (the input). Algie is trying to minimize the probability of a failure, while Imperia is trying to maximize it.

We will consider a series of 4 games, and show that the changes only make the situation better for Algie and worse for Imperia.

Game 1: $\min_\CA \max_x \Pr_{A \sim \CA}[A\text{ fails on }x]$. First, Algie chooses a distribution $\CA$ over deterministic algorithms (aka a randomized algorithm), then Imperia chooses a single input $x$.
Game 2: $\min_\CA \max_\CX \Pr_{A \sim \CA, x \sim \CX}[A\text{ fails on }x]$. Instead of choosing a single input $x$, Imperia gets to choose a distribution $\CX$ over inputs. But since she’s going second, she knows $\CA$, so she can figure out which $x$ gives her the best outcome and put all her weight on it. Therefore the outcome doesn’t change.
Game 3: $\max_\CX \min_\CA \Pr_{A \sim \CA, x \sim \CX}[A\text{ fails on }x]$. The order of the players is swapped. Intuitively, it’s always better to go second, because you have more information. Therefore, this can only make the outcome better for Algie.² The other direction (which we don’t need) is by von Neumann’s minimax theorem.
Game 4: $\max_\CX \min_A \Pr_{x \sim \CX}[A\text{ fails on }x]$. Instead of choosing a distribution $\CA$, Algie must choose a single algorithm $A$. But again, since Algie goes second, he doesn’t care.

Since Game 4 is better for Algie, if we show that Game 4 is tough for him, so is Game 1.

This is the most useful direction, but the opposite direction is also true (though slightly harder to prove). ↩
Whatever his optimal move was in Game 2, he can just do that here and get a score that’s at least as good: Suppose $\min_\CA \max_\CX \Pr_{\CA,\CX}[\cdot] = v$. This means there must be some specific randomized algorithm $\CA^*$ such that $\max_\CX \Pr_{ \CA^*,\CX}[\cdot] = v$ But then $\max_\CX \min_\CA \Pr_{\CA, \CX}[\cdot] \leq \max_\CX \Pr_{\CA^*, \CX}[\cdot] = v$. ↩