Due to compiler and hardware optimizations, modern programming languages (PLs) do not provide sequential consistent memory model (SC,[Lamport:TC79]), which guarantees that all concurrent behaviors of a program could be explained as a sequential execution of some interleaving of program's threads. Instead, they have weak memory models which allow more behaviors.
Such memory models have to balance between performance and guarantees provided to software developers, or, as one may say, the balance is actually between performance and sanity. That is, performance forces a memory model to allow more optimizations and, therefore, more program behaviors, whereas sanity forces a memory model to provide guarantees like data-race-freedom (DRF) that a program without races has only sequentially consistent executions which restricts the set of allowed executions.
In this talk, we introduce weak memory concurrency, consider requirements imposed on PL memory models, and examine ones used by industry (C11 [Batty-al:POPL11] and Java [Manson-al:POPL05]) and their drawbacks. Then, we explore new memory models (RC11 [Lahav-al:PLDI17], MRD [Paviotti-al:ESOP20], Promising 1.0 [Kang-al:POPL17], Promising 2.0 [Hwan-al:PLDI20], Weakestmo [Chakraborty-Vafeiadis:POPL19]) proposed as a solution for the drawbacks: what these models provide, which compromises they take, how expensive performance-wise, if at all, these compromises are, and how hard is to adapt the models for mainstream languages. We conclude with a discussion on how to choose a memory model for your language or VM depending on your desiderata.
Target audience:
- folks interested in low-level concurrency mechanics;
- language and VM developers.
Audience takeaway: 1) Memory models of mainstream languages (C/C++ and Java) have major issues. 2) There are solutions making different compromises. 3) There are guidelines for choosing or modifying a memory model for your language or VM.
Program committee comment
Anton is a great researcher who knows everything about memory models. Now he is mainly focused on the Intermediate Memory Model (IMM [http://plv.mpi-sws.org/imm]) project, which should modularize the correctness proofs of compilation from programming languages to mainstream multi-core architectures.
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