Gap-Majority Lemmas in Communication Complexity
Abstract
We prove an information-theoretically optimal gap-majority lemma in the two-player randomized communication model. For a base function f: X \ 1\, its n-fold gap-majority composition, denoted GapMAJ fn, takes n inputs (X1, …, Xn) and distinguishes whether f+n(X1,…,Xn) := f(X1) + … + f(Xn) is at least 0.01n or at most -0.01n. We show that if computing f with success probability 0.501 requires I bits of information, then computing GapMAJ fn with success probability 0.99 requires n · (I - O(1)) bits of information. This result is asymptotically optimal in two aspects: it achieves the correct linear scaling of information cost and the correct constant-constant tradeoff between error rates. This makes GapMAJ, to our knowledge, only the third explicit outer gadget that admits a strong composition theorem in the two-player communication setting, following the identity and XOR gadgets. From an application side, our gap-majority lemma can be viewed as a generic amplification tool that lifts the hardness of deciding f into the hardness of approximating f+n. Using this framework, we give a new proof to the communication lower bound of Gap-Hamming and derive a tight streaming lower bound of triangle counting, demonstrating the versatility of the gap-majority lemma.
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