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1. Quantitative Weakest Hyper Pre: Unifying Correctness and Incorrectness Hyperproperties via Predicate Transformers

Author

Zhang, Linpeng, Zilberstein, Noam, Kaminski, Benjamin Lucien, and Silva, Alexandra

Subjects
Computer Science - Logic in Computer Science, Computer Science - Cryptography and Security, Computer Science - Formal Languages and Automata Theory, Computer Science - Programming Languages
Abstract

We present a novel \emph{weakest pre calculus} for \emph{reasoning about quantitative hyperproperties} over \emph{nondeterministic and probabilistic} programs. Whereas existing calculi allow reasoning about the expected value that a quantity assumes after program termination from a \emph{single initial state}, we do so for \emph{initial sets of states} or \emph{initial probability distributions}. We thus (i)~obtain a weakest pre calculus for hyper Hoare logic and (ii)~enable reasoning about so-called \emph{hyperquantities} which include expected values but also quantities (e.g. variance) out of scope of previous work. As a byproduct, we obtain a novel strongest post for weighted programs that extends both existing strongest and strongest liberal post calculi. Our framework reveals novel dualities between forward and backward transformers, correctness and incorrectness, as well as nontermination and unreachability.

Published
2024

2. A Deductive Verification Infrastructure for Probabilistic Programs (Extended Version)

Author

Schröer, Philipp, Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Programming Languages
Abstract

This paper presents a quantitative program verification infrastructure for discrete probabilistic programs. Our infrastructure can be viewed as the probabilistic analogue of Boogie: its central components are an intermediate verification language (IVL) together with a real-valued logic. Our IVL provides a programming-language-style for expressing verification conditions whose validity implies the correctness of a program under investigation. As our focus is on verifying quantitative properties such as bounds on expected outcomes, expected run-times, or termination probabilities, off-the-shelf IVLs based on Boolean first-order logic do not suffice. Instead, a paradigm shift from the standard Boolean to a real-valued domain is required. Our IVL features quantitative generalizations of standard verification constructs such as assume- and assert-statements. Verification conditions are generated by a weakest-precondition-style semantics, based on our real-valued logic. We show that our verification infrastructure supports natural encodings of numerous verification techniques from the literature. With our SMT-based implementation, we automatically verify a variety of benchmarks. To the best of our knowledge, this establishes the first deductive verification infrastructure for expectation-based reasoning about probabilistic programs., Comment: This is the extended version of the the publication at OOPSLA 2023 (https://doi.org/10.1145/3622870)

Published
2023
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4. Lower Bounds for Possibly Divergent Probabilistic Programs

Author

Feng, Shenghua, Chen, Mingshuai, Su, Han, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Zhan, Naijun

Subjects
Computer Science - Logic in Computer Science, Mathematics - Probability
Abstract

We present a new proof rule for verifying lower bounds on quantities of probabilistic programs. Our proof rule is not confined to almost-surely terminating programs -- as is the case for existing rules -- and can be used to establish non-trivial lower bounds on, e.g., termination probabilities and expected values, for possibly divergent probabilistic loops, e.g., the well-known three-dimensional random walk on a lattice., Comment: Paper conditionally accepted by OOPSLA 2023

Published
2023

5. A Calculus for Amortized Expected Runtimes

Author

Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, and Verscht, Lena

Subjects
Computer Science - Logic in Computer Science
Abstract

We develop a weakest-precondition-style calculus \`a la Dijkstra for reasoning about amortized expected runtimes of randomized algorithms with access to dynamic memory - the $\textsf{aert}$ calculus. Our calculus is truly quantitative, i.e. instead of Boolean valued predicates, it manipulates real-valued functions. En route to the $\textsf{aert}$ calculus, we study the $\textsf{ert}$ calculus for reasoning about expected runtimes of Kaminski et al. [2018] extended by capabilities for handling dynamic memory, thus enabling compositional and local reasoning about randomized data structures. This extension employs runtime separation logic, which has been foreshadowed by Matheja [2020] and then implemented in Isabelle/HOL by Haslbeck [2021]. In addition to Haslbeck's results, we further prove soundness of the so-extended $\textsf{ert}$ calculus with respect to an operational Markov decision process model featuring countably-branching nondeterminism, provide intuitive explanations, and provide proof rules enabling separation logic-style verification for upper bounds on expected runtimes. Finally, we build the so-called potential method for amortized analysis into the $\textsf{ert}$ calculus, thus obtaining the $\textsf{aert}$ calculus. Since one needs to be able to handle changes in potential which can be negative, the $\textsf{aert}$ calculus needs to be capable of handling signed random variables. A particularly pleasing feature of our solution is that, unlike e.g. Kozen [1985], we obtain a loop rule for our signed random variables, and furthermore, unlike e.g. Kaminski and Katoen [2017], the $\textsf{aert}$ calculus makes do without the need for involved technical machinery keeping track of the integrability of the random variables. Finally, we present case studies, including a formal analysis of a randomized delete-insert-find-any set data structure [Brodal et al. 1996].

Published
2022

6. Probabilistic Program Verification via Inductive Synthesis of Inductive Invariants

Author

Batz, Kevin, Chen, Mingshuai, Junges, Sebastian, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Logic in Computer Science
Abstract

Essential tasks for the verification of probabilistic programs include bounding expected outcomes and proving termination in finite expected runtime. We contribute a simple yet effective inductive synthesis approach for proving such quantitative reachability properties by generating inductive invariants on source-code level. Our implementation shows promise: It finds invariants for (in)finite-state programs, can beat state-of-the-art probabilistic model checkers, and is competitive with modern tools dedicated to invariant synthesis and expected runtime reasoning.

Published
2022

7. Weighted Programming

Author

Batz, Kevin, Gallus, Adrian, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Winkler, Tobias

Subjects
Computer Science - Programming Languages, Computer Science - Machine Learning, Computer Science - Logic in Computer Science, F.3.2
Abstract

We study weighted programming, a programming paradigm for specifying mathematical models. More specifically, the weighted programs we investigate are like usual imperative programs with two additional features: (1) nondeterministic branching and (2) weighting execution traces. Weights can be numbers but also other objects like words from an alphabet, polynomials, formal power series, or cardinal numbers. We argue that weighted programming as a paradigm can be used to specify mathematical models beyond probability distributions (as is done in probabilistic programming). We develop weakest-precondition- and weakest-liberal-precondition-style calculi \`{a} la Dijkstra for reasoning about mathematical models specified by weighted programs. We present several case studies. For instance, we use weighted programming to model the ski rental problem - an optimization problem. We model not only the optimization problem itself, but also the best deterministic online algorithm for solving this problem as weighted programs. By means of weakest-precondition-style reasoning, we can determine the competitive ratio of the online algorithm on source code level., Comment: 71 pages

Published
2022

8. Quantitative Strongest Post

Author

Zhang, Linpeng and Kaminski, Benjamin Lucien

Subjects
Computer Science - Logic in Computer Science, Computer Science - Cryptography and Security, Computer Science - Programming Languages
Abstract

We present a novel strongest-postcondition-style calculus for quantitative reasoning about non-deterministic programs with loops. Whereas existing quantitative weakest pre allows reasoning about the value of a quantity after a program terminates on a given initial state, quantitative strongest post allows reasoning about the value that a quantity had before the program was executed and reached a given final state. We show how strongest post enables reasoning about the flow of quantitative information through programs. Similarly to weakest liberal preconditions, we also develop a quantitative strongest liberal post. As a byproduct, we obtain the entirely unexplored notion of strongest liberal postconditions and show how these foreshadow a potential new program logic - partial incorrectness logic - which would be a more liberal version of O'Hearn's recent incorrectness logic., Comment: Full version of a conference paper presented at OOPSLA 2022

Published
2022

9. Latticed $k$-Induction with an Application to Probabilistic Programs

Author

Batz, Kevin, Chen, Mingshuai, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, and Schröer, Philipp

Subjects
Computer Science - Logic in Computer Science
Abstract

We revisit two well-established verification techniques, $k$-induction and bounded model checking (BMC), in the more general setting of fixed point theory over complete lattices. Our main theoretical contribution is latticed $k$-induction, which (i) generalizes classical $k$-induction for verifying transition systems, (ii) generalizes Park induction for bounding fixed points of monotonic maps on complete lattices, and (iii) extends from naturals $k$ to transfinite ordinals $\kappa$, thus yielding $\kappa$-induction. The lattice-theoretic understanding of $k$-induction and BMC enables us to apply both techniques to the fully automatic verification of infinite-state probabilistic programs. Our prototypical implementation manages to automatically verify non-trivial specifications for probabilistic programs taken from the literature that - using existing techniques - cannot be verified without synthesizing a stronger inductive invariant first., Comment: to be published in: CAV (2021)

Published
2021

10. Probabilistic Data with Continuous Distributions

Author

Grohe, Martin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Lindner, Peter

Subjects
Computer Science - Databases
Abstract

Statistical models of real world data typically involve continuous probability distributions such as normal, Laplace, or exponential distributions. Such distributions are supported by many probabilistic modelling formalisms, including probabilistic database systems. Yet, the traditional theoretical framework of probabilistic databases focusses entirely on finite probabilistic databases. Only recently, we set out to develop the mathematical theory of infinite probabilistic databases. The present paper is an exposition of two recent papers which are cornerstones of this theory. In (Grohe, Lindner; ICDT 2020) we propose a very general framework for probabilistic databases, possibly involving continuous probability distributions, and show that queries have a well-defined semantics in this framework. In (Grohe, Kaminski, Katoen, Lindner; PODS 2020) we extend the declarative probabilistic programming language Generative Datalog, proposed by (B\'ar\'any et al.~2017) for discrete probability distributions, to continuous probability distributions and show that such programs yield generative models of continuous probabilistic databases.

Published
2021

11. Probabilistic Program Verification via Inductive Synthesis of Inductive Invariants

Author

Batz, Kevin, Chen, Mingshuai, Junges, Sebastian, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Sankaranarayanan, Sriram, editor, and Sharygina, Natasha, editor

Published
2023
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12. Relatively Complete Verification of Probabilistic Programs

Author

Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages
Abstract

We study a syntax for specifying quantitative "assertions" - functions mapping program states to numbers - for probabilistic program verification. We prove that our syntax is expressive in the following sense: Given any probabilistic program $C$, if a function $f$ is expressible in our syntax, then the function mapping each initial state $\sigma$ to the expected value of $f$ evaluated in the final states reached after termination of $C$ on $\sigma$ (also called the weakest preexpectation $\textit{wp} [C](f)$) is also expressible in our syntax. As a consequence, we obtain a relatively complete verification system for reasoning about expected values and probabilities in the sense of Cook: Apart from proving a single inequality between two functions given by syntactic expressions in our language, given $f$, $g$, and $C$, we can check whether $g \preceq \textit{wp} [C] (f)$.

Published
2020

13. Generating Functions for Probabilistic Programs

Author

Klinkenberg, Lutz, Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Moerman, Joshua, and Winkler, Tobias

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages
Abstract

This paper investigates the usage of generating functions (GFs) encoding measures over the program variables for reasoning about discrete probabilistic programs. To that end, we define a denotational GF-transformer semantics for probabilistic while-programs, and show that it instantiates Kozen's seminal distribution transformer semantics. We then study the effective usage of GFs for program analysis. We show that finitely expressible GFs enable checking super-invariants by means of computer algebra tools, and that they can be used to determine termination probabilities. The paper concludes by characterizing a class of -- possibly infinite-state -- programs whose semantics is a rational GF encoding a discrete phase-type distribution.

Published
2020

14. PrIC3: Property Directed Reachability for MDPs

Author

Batz, Kevin, Junges, Sebastian, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, and Schröer, Philipp

Subjects
Computer Science - Logic in Computer Science
Abstract

IC3 has been a leap forward in symbolic model checking. This paper proposes PrIC3 (pronounced pricy-three), a conservative extension of IC3 to symbolic model checking of MDPs. Our main focus is to develop the theory underlying PrIC3. Alongside, we present a first implementation of PrIC3 including the key ingredients from IC3 such as generalization, repushing, and propagation.

Published
2020

15. Generative Datalog with Continuous Distributions

Author

Grohe, Martin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Lindner, Peter

Subjects
Computer Science - Databases, Computer Science - Logic in Computer Science
Abstract

Arguing for the need to combine declarative and probabilistic programming, B\'ar\'any et al. (TODS 2017) recently introduced a probabilistic extension of Datalog as a "purely declarative probabilistic programming language." We revisit this language and propose a more principled approach towards defining its semantics based on stochastic kernels and Markov processes - standard notions from probability theory. This allows us to extend the semantics to continuous probability distributions, thereby settling an open problem posed by B\'ar\'any et al. We show that our semantics is fairly robust, allowing both parallel execution and arbitrary chase orders when evaluating a program. We cast our semantics in the framework of infinite probabilistic databases (Grohe and Lindner, ICDT 2020), and show that the semantics remains meaningful even when the input of a probabilistic Datalog program is an arbitrary probabilistic database., Comment: Extended Version

Published
2020

16. Optimistic Value Iteration

Author

Hartmanns, Arnd and Kaminski, Benjamin Lucien

Subjects
Computer Science - Logic in Computer Science, Computer Science - Formal Languages and Automata Theory
Abstract

Markov decision processes are widely used for planning and verification in settings that combine controllable or adversarial choices with probabilistic behaviour. The standard analysis algorithm, value iteration, only provides a lower bound on unbounded probabilities or reward values. Two "sound" variations, which also deliver an upper bound, have recently appeared. In this paper, we present optimistic value iteration, a new sound approach that leverages value iteration's ability to usually deliver tight lower bounds: we obtain a lower bound via standard value iteration, use the result to "guess" an upper bound, and prove the latter's correctness. Optimistic value iteration is easy to implement, does not require extra precomputations or a priori state space transformations, and works for computing reachability probabilities as well as expected rewards. It is also fast, as we show via an extensive experimental evaluation using our publicly available implementation within the Modest Toolset.

Published
2019

17. Aiming Low Is Harder -- Induction for Lower Bounds in Probabilistic Program Verification

Author

Hark, Marcel, Kaminski, Benjamin Lucien, Giesl, Jürgen, and Katoen, Joost-Pieter

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages
Abstract

We present a new inductive rule for verifying lower bounds on expected values of random variables after execution of probabilistic loops as well as on their expected runtimes. Our rule is simple in the sense that loop body semantics need to be applied only finitely often in order to verify that the candidates are indeed lower bounds. In particular, it is not necessary to find the limit of a sequence as in many previous rules.

Published
2019
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18. A Pre-Expectation Calculus for Probabilistic Sensitivity

Author

Aguirre, Alejandro, Barthe, Gilles, Hsu, Justin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages
Abstract

Sensitivity properties describe how changes to the input of a program affect the output, typically by upper bounding the distance between the outputs of two runs by a monotone function of the distance between the corresponding inputs. When programs are probabilistic, the distance between outputs is a distance between distributions. The Kantorovich lifting provides a general way of defining a distance between distributions by lifting the distance of the underlying sample space; by choosing an appropriate distance on the base space, one can recover other usual probabilistic distances, such as the Total Variation distance. We develop a relational pre-expectation calculus to upper bound the Kantorovich distance between two executions of a probabilistic program. We illustrate our methods by proving algorithmic stability of a machine learning algorithm, convergence of a reinforcement learning algorithm, and fast mixing for card shuffling algorithms. We also consider some extensions: proving lower bounds on the Total Variation distance and convergence to the uniform distribution. Finally, we describe an asynchronous extension of our calculus to reason about pairs of program executions with different control flow., Comment: Major revision

Published
2019

20. Quantitative Separation Logic - A Logic for Reasoning about Probabilistic Programs

Author

Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, and Noll, Thomas

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages
Abstract

We present quantitative separation logic ($\mathsf{QSL}$). In contrast to classical separation logic, $\mathsf{QSL}$ employs quantities which evaluate to real numbers instead of predicates which evaluate to Boolean values. The connectives of classical separation logic, separating conjunction and separating implication, are lifted from predicates to quantities. This extension is conservative: Both connectives are backward compatible to their classical analogs and obey the same laws, e.g. modus ponens, adjointness, etc. Furthermore, we develop a weakest precondition calculus for quantitative reasoning about probabilistic pointer programs in $\mathsf{QSL}$. This calculus is a conservative extension of both Reynolds' separation logic for heap-manipulating programs and Kozen's / McIver and Morgan's weakest preexpectations for probabilistic programs. Soundness is proven with respect to an operational semantics based on Markov decision processes. Our calculus preserves O'Hearn's frame rule, which enables local reasoning. We demonstrate that our calculus enables reasoning about quantities such as the probability of terminating with an empty heap, the probability of reaching a certain array permutation, or the expected length of a list.

Published
2018
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21. How long, O Bayesian network, will I sample thee? A program analysis perspective on expected sampling times

Author

Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Programming Languages
Abstract

Bayesian networks (BNs) are probabilistic graphical models for describing complex joint probability distributions. The main problem for BNs is inference: Determine the probability of an event given observed evidence. Since exact inference is often infeasible for large BNs, popular approximate inference methods rely on sampling. We study the problem of determining the expected time to obtain a single valid sample from a BN. To this end, we translate the BN together with observations into a probabilistic program. We provide proof rules that yield the exact expected runtime of this program in a fully automated fashion. We implemented our approach and successfully analyzed various real-world BNs taken from the Bayesian network repository.

Published
2018

22. A New Proof Rule for Almost-Sure Termination

Author

McIver, Annabelle, Morgan, Carroll, Kaminski, Benjamin Lucien, and Katoen, Joost-Pieter

Subjects
Computer Science - Programming Languages, Computer Science - Logic in Computer Science
Abstract

An important question for a probabilistic program is whether the probability mass of all its diverging runs is zero, that is that it terminates "almost surely". Proving that can be hard, and this paper presents a new method for doing so; it is expressed in a program logic, and so applies directly to source code. The programs may contain both probabilistic- and demonic choice, and the probabilistic choices may depend on the current state. As do other researchers, we use variant functions (a.k.a. "super-martingales") that are real-valued and probabilistically might decrease on each loop iteration; but our key innovation is that the amount as well as the probability of the decrease are parametric. We prove the soundness of the new rule, indicate where its applicability goes beyond existing rules, and explain its connection to classical results on denumerable (non-demonic) Markov chains., Comment: V1 to appear in PoPL18. This version collects some existing text into new example subsection 5.5 and adds a new example 5.6 and makes further remarks about uncountable branching. The new example 5.6 relates to work on lexicographic termination methods, also to appear in PoPL18 [Agrawal et al, 2018]

Published
2017

23. A Weakest Pre-Expectation Semantics for Mixed-Sign Expectations

Author

Kaminski, Benjamin Lucien and Katoen, Joost-Pieter

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages, D.2.4, D.3.1, F.1.2, F.3.1, F.3.2
Abstract

We present a weakest-precondition-style calculus for reasoning about the expected values (pre-expectations) of \emph{mixed-sign unbounded} random variables after execution of a probabilistic program. The semantics of a while-loop is well-defined as the limit of iteratively applying a functional to a zero-element just as in the traditional weakest pre-expectation calculus, even though a standard least fixed point argument is not applicable in this context. A striking feature of our semantics is that it is always well-defined, even if the expected values do not exist. We show that the calculus is sound, allows for compositional reasoning, and present an invariant-based approach for reasoning about pre-expectations of loops.

Published
2017

24. Latticed k-Induction with an Application to Probabilistic Programs

Author

Batz, Kevin, Chen, Mingshuai, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, Schröer, Philipp, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Silva, Alexandra, editor, and Leino, K. Rustan M., editor

Published
2021
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25. Generating Functions for Probabilistic Programs

Author

Klinkenberg, Lutz, Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Moerman, Joshua, Winkler, Tobias, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, and Fernández, Maribel, editor

Published
2021
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26. Optimistic Value Iteration

Author

Hartmanns, Arnd, Kaminski, Benjamin Lucien, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Woeginger, Gerhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Lahiri, Shuvendu K., editor, and Wang, Chao, editor

Published
2020
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27. Inferring Covariances for Probabilistic Programs

Author

Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Logic in Computer Science
Abstract

We study weakest precondition reasoning about the (co)variance of outcomes and the variance of run-times of probabilistic programs with conditioning. For outcomes, we show that approximating (co)variances is computationally more difficult than approximating expected values. In particular, we prove that computing both lower and upper bounds for (co)variances is $\Sigma^{0}_{2}$-complete. As a consequence, neither lower nor upper bounds are computably enumerable. We therefore present invariant-based techniques that do enable enumeration of both upper and lower bounds, once appropriate invariants are found. Finally, we extend this approach to reasoning about run-time variances.

Published
2016

28. Bounded Model Checking for Probabilistic Programs

Author

Jansen, Nils, Dehnert, Christian, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Westhofen, Lukas

Subjects
Computer Science - Programming Languages
Abstract

In this paper we investigate the applicability of standard model checking approaches to verifying properties in probabilistic programming. As the operational model for a standard probabilistic program is a potentially infinite parametric Markov decision process, no direct adaption of existing techniques is possible. Therefore, we propose an on-the-fly approach where the operational model is successively created and verified via a step-wise execution of the program. This approach enables to take key features of many probabilistic programs into account: nondeterminism and conditioning. We discuss the restrictions and demonstrate the scalability on several benchmarks.

Published
2016

29. Reasoning about Recursive Probabilistic Programs

Author

Olmedo, Federico, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Subjects
Computer Science - Logic in Computer Science
Abstract

This paper presents a wp-style calculus for obtaining expectations on the outcomes of (mutually) recursive probabilistic programs. We provide several proof rules to derive one-- and two--sided bounds for such expectations, and show the soundness of our wp-calculus with respect to a probabilistic pushdown automaton semantics. We also give a wp-style calculus for obtaining bounds on the expected runtime of recursive programs that can be used to determine the (possibly infinite) time until termination of such programs.

Published
2016

30. Weakest Precondition Reasoning for Expected Run-Times of Probabilistic Programs

Author

Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, and Olmedo, Federico

Subjects
Computer Science - Logic in Computer Science, Computer Science - Programming Languages
Abstract

This paper presents a wp-style calculus for obtaining bounds on the expected run-time of probabilistic programs. Its application includes determining the (possibly infinite) expected termination time of a probabilistic program and proving positive almost-sure termination - does a program terminate with probability one in finite expected time? We provide several proof rules for bounding the run-time of loops, and prove the soundness of the approach with respect to a simple operational model. We show that our approach is a conservative extension of Nielson's approach for reasoning about the run-time of deterministic programs. We analyze the expected run-time of some example programs including a one-dimensional random walk and the coupon collector problem.

Published
2016

31. On the Hardness of Almost-Sure Termination

Author

Kaminski, Benjamin Lucien and Katoen, Joost-Pieter

Subjects
Computer Science - Logic in Computer Science, Computer Science - Computational Complexity, F.1.2, F.1.3, F.4.1
Abstract

This paper considers the computational hardness of computing expected outcomes and deciding (universal) (positive) almost-sure termination of probabilistic programs. It is shown that computing lower and upper bounds of expected outcomes is $\Sigma_1^0$- and $\Sigma_2^0$-complete, respectively. Deciding (universal) almost-sure termination as well as deciding whether the expected outcome of a program equals a given rational value is shown to be $\Pi^0_2$-complete. Finally, it is shown that deciding (universal) positive almost-sure termination is $\Sigma_2^0$-complete ($\Pi_3^0$-complete)., Comment: MFCS 2015. arXiv admin note: text overlap with arXiv:1410.7225

Published
2015

32. Conditioning in Probabilistic Programming

Author

Gretz, Friedrich, Jansen, Nils, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, McIver, Annabelle, and Olmedo, Federico

Subjects
Computer Science - Programming Languages
Abstract

We investigate the semantic intricacies of conditioning, a main feature in probabilistic programming. We provide a weakest (liberal) pre-condition (w(l)p) semantics for the elementary probabilistic programming language pGCL extended with conditioning. We prove that quantitative weakest (liberal) pre-conditions coincide with conditional (liberal) expected rewards in Markov chains and show that semantically conditioning is a truly conservative extension. We present two program transformations which entirely eliminate conditioning from any program and prove their correctness using the w(l)p-semantics. Finally, we show how the w(l)p-semantics can be used to determine conditional probabilities in a parametric anonymity protocol and show that an inductive w(l)p-semantics for conditioning in non-deterministic probabilistic programs cannot exist.

Published
2015

33. Analyzing Expected Outcomes and Almost-Sure Termination of Probabilistic Programs is Hard

Author

Kaminski, Benjamin Lucien and Katoen, Joost-Pieter

Subjects
Computer Science - Logic in Computer Science, 68Q87, F.1.2, F.1.3, F.4.1
Abstract

This paper considers the computational hardness of computing expected outcomes and deciding almost-sure termination of probabilistic programs. We show that deciding almost-sure termination and deciding whether the expected outcome of a program equals a given rational value is $\Pi^0_2$-complete. Computing lower and upper bounds on the expected outcome is shown to be recursively enumerable and $\Sigma^0_2$-complete, respectively.

Published
2014

36. Generative Datalog with Continuous Distributions.

Author

GROHE, MARTIN, KAMINSKI, BENJAMIN LUCIEN, KATOEN, JOOST-PIETER, and LINDNER, PETER

Subjects
CONTINUOUS distributions, PROGRAMMING languages, PROBABILITY theory, MARKOV processes, DISTRIBUTION (Probability theory), PROBABILISTIC databases, KERNEL operating systems
Abstract

Arguing for the need to combine declarative and probabilistic programming, Bárány et al. (TODS 2017) recently introduced a probabilistic extension of Datalog as a “purely declarative probabilistic programming language.” We revisit this language and propose a more principled approach towards defining its semantics based on stochastic kernels and Markov processes—standard notions from probability theory. This allows us to extend the semantics to continuous probability distributions, thereby settling an open problem posed by Bárány et al. We show that our semantics is fairly robust, allowing both parallel execution and arbitrary chase orders when evaluating a program.We cast our semantics in the framework of infinite probabilistic databases (Grohe and Lindner, LMCS 2022) and show that the semantics remains meaningful even when the input of a probabilistic Datalog program is an arbitrary probabilistic database. [ABSTRACT FROM AUTHOR]

Published
2022
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41. Understanding Probabilistic Programs

Author

Katoen, Joost-Pieter, Gretz, Friedrich, Jansen, Nils, Kaminski, Benjamin Lucien, Olmedo, Federico, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Meyer, Roland, editor, Platzer, André, editor, and Wehrheim, Heike, editor

Published
2015
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43. A Deductive Verification Infrastructure for Probabilistic Programs

Author

Schröer, Philipp, Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, Matheja, Christoph, Schröer, Philipp, Batz, Kevin, Kaminski, Benjamin Lucien, Katoen, Joost-Pieter, and Matheja, Christoph

Abstract

This paper presents a quantitative program verification infrastructure for discrete probabilistic programs. Our infrastructure can be viewed as the probabilistic analogue of Boogie: its central components are an intermediate verification language (IVL) together with a real-valued logic. Our IVL provides a programming-language-style for expressing verification conditions whose validity implies the correctness of a program under investigation. As our focus is on verifying quantitative properties such as bounds on expected outcomes, expected run-times, or termination probabilities, off-the-shelf IVLs based on Boolean first-order logic do not suffice. Instead, a paradigm shift from the standard Boolean to a real-valued domain is required. Our IVL features quantitative generalizations of standard verification constructs such as assume- and assert-statements. Verification conditions are generated by a weakest-precondition-style semantics, based on our real-valued logic. We show that our verification infrastructure supports natural encodings of numerous verification techniques from the literature. With our SMT-based implementation, we automatically verify a variety of benchmarks. To the best of our knowledge, this establishes the first deductive verification infrastructure for expectation-based reasoning about probabilistic programs.

Published
2023

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