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1. Long term variability of Cygnus X-1. VIII. A spectral-timing look at low energies with NICER

Author

König, Ole, Mastroserio, Guglielmo, Dauser, Thomas, Méndez, Mariano, Wang, Jingyi, García, Javier A., Steiner, James F., Pottschmidt, Katja, Ballhausen, Ralf, Connors, Riley M., García, Federico, Grinberg, Victoria, Horn, David, Ingram, Adam, Kara, Erin, Kallman, Timothy R., Lucchini, Matteo, Nathan, Edward, Nowak, Michael A., Thalhammer, Philipp, van der Klis, Michiel, and Wilms, Jörn

Subjects
Astrophysics - High Energy Astrophysical Phenomena, High Energy Physics - Experiment, High Energy Physics - Phenomenology
Abstract

The Neutron Star Interior Composition Explorer (NICER) monitoring campaign of Cyg X-1 allows us to study its spectral-timing behavior at energies ${<}1$ keV across all states. The hard state power spectrum can be decomposed into two main broad Lorentzians with a transition at around 1 Hz. The lower-frequency Lorentzian is the dominant component at low energies. The higher-frequency Lorentzian begins to contribute significantly to the variability above 1.5 keV and dominates at high energies. We show that the low- and high-frequency Lorentzians likely represent individual physical processes. The lower-frequency Lorentzian can be associated with a (possibly Comptonized) disk component, while the higher-frequency Lorentzian is clearly associated with the Comptonizing plasma. At the transition of these components, we discover a low-energy timing phenomenon characterized by an abrupt lag change of hard (${\gtrsim}2$ keV) with respect to soft (${\lesssim}1.5$ keV) photons, accompanied by a drop in coherence, and a reduction in amplitude of the second broad Lorentzian. The frequency of the phenomenon increases with the frequencies of the Lorentzians as the source softens and cannot be seen when the power spectrum is single-humped. A comparison to transient low-mass X-ray binaries shows that this feature does not only appear in Cyg X-1, but that it is a general property of accreting black hole binaries. In Cyg X-1, we find that the variability at low and high energies is overall highly coherent in the hard and intermediate states. The high coherence shows that there is a process at work which links the variability, suggesting a physical connection between the accretion disk and Comptonizing plasma. This process fundamentally changes in the soft state, where strong red noise at high energies is incoherent to the variability at low energies., Comment: 18+29 pages, 17+54 figures, accepted for publication in Astronomy & Astrophysics

Published
2024
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4. Absynthe: Abstract Interpretation-Guided Synthesis

Author

Guria, Sankha Narayan, Foster, Jeffrey S., and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Synthesis tools have seen significant success in recent times. However, past approaches often require a complete and accurate embedding of the source language in the logic of the underlying solver, an approach difficult for industrial-grade languages. Other approaches couple the semantics of the source language with purpose-built synthesizers, necessarily tying the synthesis engine to a particular language model. In this paper, we propose Absynthe, an alternative approach based on user-defined abstract semantics that aims to be both lightweight and language agnostic, yet effective in guiding the search for programs. A synthesis goal in Absynthe is specified as an abstract specification in a lightweight user-defined abstract domain and concrete test cases. The synthesis engine is parameterized by the abstract semantics and independent of the source language. Absynthe validates candidate programs against test cases using the actual concrete language implementation to ensure correctness. We formalize the synthesis rules for Absynthe and describe how the key ideas are scaled-up in our implementation in Ruby. We evaluated Absynthe on SyGuS strings benchmark and found it competitive with other enumerative search solvers. Moreover, Absynthe's ability to combine abstract domains allows the user to move along a cost spectrum, i.e., expressive domains prune more programs but require more time. Finally, to verify Absynthe can act as a general purpose synthesis tool, we use Absynthe to synthesize Pandas data frame manipulating programs in Python using simple abstractions like types and column labels of a data frame. Absynthe reaches parity with AutoPandas, a deep learning based tool for the same benchmark suite. In summary, our results demonstrate Absynthe is a promising step forward towards a general-purpose approach to synthesis that may broaden the applicability of synthesis to more $\ldots$, Comment: 22 pages, 6 figures, this is a preprint of a paper conditionally accepted at Programming Language Design and Implementation (PLDI) 2023

Published
2023
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5. NICER/NuSTAR Characterization of 4U 1957+11: A Near Maximally Spinning Black Hole Potentially in the Mass Gap

Author

Barillier, Erin, Grinberg, Victoria, Horn, David, Nowak, Michael A., Remillard, Ronald A., Steiner, James F., Walton, Dominic J., and Wilms, Jörn

Subjects
Astrophysics - High Energy Astrophysical Phenomena
Abstract

4U 1957+11 is a black hole candidate system that has been in a soft X-ray spectral state since its discovery. We present analyses of recent joint NICER and NuSTAR spectra, which are extremely well-described by a highly inclined disk accreting into a near maximally spinning black hole. Owing to the broad X-ray coverage of NuSTAR the fitted spin and inclination are strongly constrained for our hypothesized disk models. The faintest spectra are observed out to 20 keV, even though their hard tail components are almost absent when described with a simple corona. The hard tail increases with luminosity, but shows clear two track behavior with one track having appreciably stronger tails. The disk spectrum color-correction factor is anti-correlated with the strength of the hard tail (e.g., as measured by the Compton $y$ parameter). Although the spin and inclination parameters are strongly constrained for our chosen model, the mass and distance are degenerate parameters. We use our spectral fits, along with a theoretical prior on color-correction, an observational prior on likely fractional Eddington luminosity, and an observational prior on distance obtained from Gaia studies, to present mass and distance contours for this system. The most likely parameters, given our presumed disk model, suggest a 4.6 $\mathrm{M_\odot}$ black hole at 7.8 kpc observed at luminosities ranging from $\approx 1.7\%$--$9\%$ of Eddington. This would place 4U 1957+11 as one of the few actively accreting sources within the `mass gap' of ${\approx} 2$--$5\,\mathrm{M_\odot}$ where there are few known massive neutron stars or low mass black holes. Higher mass and distance, however, remain viable., Comment: 21 pages. To be published in the Astrophysical Journal

Published
2023
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9. Deep learning study of an electromagnetic calorimeter

Author

Sela, Elihu, Huang, Shan, and Horn, David

Subjects
Physics - Data Analysis, Statistics and Probability, High Energy Physics - Experiment
Abstract

The accurate and precise extraction of information from a modern particle physics detector, such as an electromagnetic calorimeter, may be complicated and challenging. In order to overcome the difficulties we propose processing the detector output using the deep-learning methodology. Our algorithmic approach makes use of a known network architecture, which is being modified to fit the problems at hand. The results are of high quality (biases of order 2%) and, moreover, indicate that most of the information may be derived from only a fraction of the detector. We conclude that such an analysis helps us understanding the essential mechanism of the detector and should be performed as a part of its designing procedure.

Published
2022

10. A Formal Model of Checked C

Author

Li, Liyi, Liu, Yiyun, Postol, Deena L., Lampropoulos, Leonidas, Van Horn, David, and Hicks, Michael

Subjects
Computer Science - Programming Languages, Computer Science - Software Engineering, D.3.1
Abstract

We present a formal model of Checked C, a dialect of C that aims to enforce spatial memory safety. Our model pays particular attention to the semantics of dynamically sized, potentially null-terminated arrays. We formalize this model in Coq, and prove that any spatial memory safety errors can be blamed on portions of the program labeled unchecked; this is a Checked C feature that supports incremental porting and backward compatibility. While our model's operational semantics uses annotated ("fat") pointers to enforce spatial safety, we show that such annotations can be safely erased: Using PLT Redex we formalize an executable version of our model and a compilation procedure from it to an untyped C-like language, and use randomized testing to validate that generated code faithfully simulates the original. Finally, we develop a custom random generator for well-typed and almost-well-typed terms in our Redex model, and use it to search for inconsistencies between our model and the Clang Checked C implementation. We find these steps to be a useful way to co-develop a language (Checked C is still in development) and a core model of it., Comment: This is an extended version of a paper that appears at the 2022 Computer Security Foundations Symposium

Published
2022

12. Educational Environments and Secondary School Outcomes among Students Who Are D/deaf and Hard of Hearing in Special Education

Author

Epstein, Sherise, Christianson, Erin, Ou, Henry C., Norton, Susan J., Sie, Kathleen C. Y., and Horn, David L.

Abstract

Purpose: The purpose of this study is to provide updated national estimates on the annual number, educational environments, and secondary school outcomes of students who are D/deaf and hard of hearing (D/HH) receiving special education (SpEd) and related services in the United States. Method: We performed a retrospective cross-sectional descriptive analysis of Individuals with Disabilities Education Act, Part B, Section 618 data from 2012 to 2018. Participants included students 6-21 years old in SpEd with "hearing impairment" reported as their primary disability. The general population of students in secondary school served as a comparator, via Current Population Survey data. We described the annual number of students: (1) overall; (2) by educational environment; and (3) by reason for exiting SpEd, including the proportion graduating from and dropping out of secondary school. We described variation over time. Results: The median annual number of students was 67,655, with minimal variation by year. The proportion in general education (GenEd) for [greater than or equal to] 80% of the day increased by 4.2% over 6 years from 57.8% to 62.0%, whereas the proportions in GenEd for < 40% and 40%-79% of the day decreased by 1.6% and 1.3%, respectively. Proportions in the remainder of the environments changed < 1.0% each. Of exiters, 86.8% of students graduated, whereas 3.9% dropped out, compared to a dropout rate of 5.0% in the general population. Conclusion: From 2012 to 2018, students who are D/HH receiving SpEd in the United States have spent increasingly more time in GenEd, most graduated from high school, and few dropped out, with dropout patterns appearing similar to the general population.

Published
2022
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14. RbSyn: Type- and Effect-Guided Program Synthesis

Author

Guria, Sankha Narayan, Foster, Jeffrey S., and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

In recent years, researchers have explored component-based synthesis, which aims to automatically construct programs that operate by composing calls to existing APIs. However, prior work has not considered efficient synthesis of methods with side effects, e.g., web app methods that update a database. In this paper, we introduce RbSyn, a novel type- and effect-guided synthesis tool for Ruby. An RbSyn synthesis goal is specified as the type for the target method and a series of test cases it must pass. RbSyn works by recursively generating well-typed candidate method bodies whose write effects match the read effects of the test case assertions. After finding a set of candidates that separately satisfy each test, RbSyn synthesizes a solution that branches to execute the correct candidate code under the appropriate conditions. We formalize RbSyn on a core, object-oriented language $\lambda_{syn}$ and describe how the key ideas of the model are scaled-up in our implementation for Ruby. We evaluated RbSyn on 19 benchmarks, 12 of which come from popular, open-source Ruby apps. We found that RbSyn synthesizes correct solutions for all benchmarks, with 15 benchmarks synthesizing in under 9 seconds, while the slowest benchmark takes 83 seconds. Using observed reads to guide synthesize is effective: using type-guidance alone times out on 10 of 12 app benchmarks. We also found that using less precise effect annotations leads to worse synthesis performance. In summary, we believe type- and effect-guided synthesis is an important step forward in synthesis of effectful methods from test cases., Comment: 17 pages, 13 figures, this is a technical report (with appendix) of a paper to appear in Programming Language Design and Implementation (PLDI) 2021

Published
2021

15. Corpse Reviver: Sound and Efficient Gradual Typing via Contract Verification

Author

Moy, Cameron, Nguyen, Phúc C., Tobin-Hochstadt, Sam, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Gradually-typed programming languages permit the incremental addition of static types to untyped programs. To remain sound, languages insert run-time checks at the boundaries between typed and untyped code. Unfortunately, performance studies have shown that the overhead of these checks can be disastrously high, calling into question the viability of sound gradual typing. In this paper, we show that by building on existing work on soft contract verification, we can reduce or eliminate this overhead. Our key insight is that while untyped code cannot be trusted by a gradual type system, there is no need to consider only the worst case when optimizing a gradually-typed program. Instead, we statically analyze the untyped portions of a gradually-typed program to prove that almost all of the dynamic checks implied by gradual type boundaries cannot fail, and can be eliminated at compile time. Our analysis is modular, and can be applied to any portion of a program. We evaluate this approach on a dozen existing gradually-typed programs previously shown to have prohibitive performance overhead---with a median overhead of $3.5\times$ and up to $73.6\times$ in the worst case---and eliminate all overhead in most cases, suffering only $1.6\times$ overhead in the worst case., Comment: To appear in POPL 2021

Published
2020

16. Spectral Resolution Development in Children with Normal Hearing and with Cochlear Implants: A Review of Behavioral Studies

Author

Jahn, Kelly N., Arenberg, Julie G., and Horn, David L.

Abstract

Purpose: This review article provides a theoretical overview of the development of spectral resolution in children with normal hearing (cNH) and in those who use cochlear implants (CIs), with an emphasis on methodological considerations. The aim was to identify key directions for future research on spectral resolution development in children with CIs. Method: A comprehensive literature review was conducted to summarize and synthesize previously published behavioral research on spectral resolution development in normal and impaired auditory systems. Conclusions: In cNH, performance on spectral resolution tasks continues to improve through the teenage years and is likely driven by gradual maturation of across-channel intensity resolution. A small but growing body of evidence from children with CIs suggests a more complex relationship between spectral resolution development, patient demographics, and the quality of the CI electrode--neuron interface. Future research should aim to distinguish between the effects of patient-specific variables and the underlying physiology on spectral resolution abilities in children of all ages who are hard of hearing and use auditory prostheses.

Published
2022
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17. Experimental nitrogen and phosphorus enrichment stimulates multiple trophic levels of algal and detrital‐based food webs: a global meta‐analysis from streams and rivers

Author

Ardón, Marcelo, Zeglin, Lydia H, Utz, Ryan M, Cooper, Scott D, Dodds, Walter K, Bixby, Rebecca J, Burdett, Ayesha S, Shah, Jennifer Follstad, Griffiths, Natalie A, Harms, Tamara K, Johnson, Sherri L, Jones, Jeremy B, Kominoski, John S, McDowell, William H, Rosemond, Amy D, Trentman, Matt T, Van Horn, David, and Ward, Amelia

Subjects
Biological Sciences, Ecology, Life on Land, lotic, eutrophication, nutrient criteria, primary and secondary production, ecosystem metabolism, decomposition, Evolutionary Biology, Biological sciences
Abstract

Anthropogenic increases in nitrogen (N) and phosphorus (P) concentrations can strongly influence the structure and function of ecosystems. Even though lotic ecosystems receive cumulative inputs of nutrients applied to and deposited on land, no comprehensive assessment has quantified nutrient-enrichment effects within streams and rivers. We conducted a meta-analysis of published studies that experimentally increased concentrations of N and/or P in streams and rivers to examine how enrichment alters ecosystem structure (state: primary producer and consumer biomass and abundance) and function (rate: primary production, leaf breakdown rates, metabolism) at multiple trophic levels (primary producer, microbial heterotroph, primary and secondary consumers, and integrated ecosystem). Our synthesis included 184 studies, 885 experiments, and 3497 biotic responses to nutrient enrichment. We documented widespread increases in organismal biomass and abundance (mean response = +48%) and rates of ecosystem processes (+54%) to enrichment across multiple trophic levels, with no large differences in responses among trophic levels or between autotrophic or heterotrophic food-web pathways. Responses to nutrient enrichment varied with the nutrient added (N, P, or both) depending on rate versus state variable and experiment type, and were greater in flume and whole-stream experiments than in experiments using nutrient-diffusing substrata. Generally, nutrient-enrichment effects also increased with water temperature and light, and decreased under elevated ambient concentrations of inorganic N and/or P. Overall, increased concentrations of N and/or P altered multiple food-web pathways and trophic levels in lotic ecosystems. Our results indicate that preservation or restoration of biodiversity and ecosystem functions of streams and rivers requires management of nutrient inputs and consideration of multiple trophic pathways.

Published
2021

20. Type-Level Computations for Ruby Libraries

Author

Kazerounian, Milod, Guria, Sankha Narayan, Vazou, Niki, Foster, Jeffrey S., and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Many researchers have explored ways to bring static typing to dynamic languages. However, to date, such systems are not precise enough when types depend on values, which often arises when using certain Ruby libraries. For example, the type safety of a database query in Ruby on Rails depends on the table and column names used in the query. To address this issue, we introduce CompRDL, a type system for Ruby that allows library method type signatures to include type-level computations (or comp types for short). Combined with singleton types for table and column names, comp types let us give database query methods type signatures that compute a table's schema to yield very precise type information. Comp types for hash, array, and string libraries can also increase precision and thereby reduce the need for type casts. We formalize CompRDL and prove its type system sound. Rather than type check the bodies of library methods with comp types---those methods may include native code or be complex---CompRDL inserts run-time checks to ensure library methods abide by their computed types. We evaluated CompRDL by writing annotations with type-level computations for several Ruby core libraries and database query APIs. We then used those annotations to type check two popular Ruby libraries and four Ruby on Rails web apps. We found the annotations were relatively compact and could successfully type check 132 methods across our subject programs. Moreover, the use of type-level computations allowed us to check more expressive properties, with fewer manually inserted casts, than was possible without type-level computations. In the process, we found two type errors and a documentation error that were confirmed by the developers. Thus, we believe CompRDL is an important step forward in bringing precise static type checking to dynamic languages., Comment: 22 pages, this is a technical report (with appendix) of a paper to appear in Programming Language Design and Implementation (PLDI 2019)

Published
2019

21. Size-Change Termination as a Contract

Author

Nguyen, Phuc C., Gilray, Thomas, Tobin-Hochstadt, Sam, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Termination is an important but undecidable program property, which has led to a large body of work on static methods for conservatively predicting or enforcing termination. One such method is the size-change termination approach of Lee, Jones, and Ben-Amram, which operates in two phases: (1) abstract programs into "size-change graphs," and (2) check these graphs for the size-change property: the existence of paths that lead to infinite decreasing sequences. We transpose these two phases with an operational semantics that accounts for the run-time enforcement of the size-change property, postponing (or entirely avoiding) program abstraction. This choice has two key consequences: (1) size-change termination can be checked at run-time and (2) termination can be rephrased as a safety property analyzed using existing methods for systematic abstraction. We formulate run-time size-change checks as contracts in the style of Findler and Felleisen. The result compliments existing contracts that enforce partial correctness specifications to obtain contracts for total correctness. Our approach combines the robustness of the size-change principle for termination with the precise information available at run-time. It has tunable overhead and can check for nontermination without the conservativeness necessary in static checking. To obtain a sound and computable termination analysis, we apply existing abstract interpretation techniques directly to the operational semantics, avoiding the need for custom abstractions for termination. The resulting analyzer is competitive with with existing, purpose-built analyzers.

Published
2018
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22. Constructive Galois Connections

Author

Darais, David and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Galois connections are a foundational tool for structuring abstraction in semantics and their use lies at the heart of the theory of abstract interpretation. Yet, mechanization of Galois connections using proof assistants remains limited to restricted modes of use, preventing their general application in mechanized metatheory and certified programming. This paper presents constructive Galois connections, a variant of Galois connections that is effective both on paper and in proof assistants; is complete with respect to a large subset of classical Galois connections; and enables more general reasoning principles, including the "calculational" style advocated by Cousot. To design constructive Galois connections we identify a restricted mode of use of classical ones which is both general and amenable to mechanization in dependently-typed functional programming languages. Crucial to our metatheory is the addition of monadic structure to Galois connections to control a "specification effect." Effectful calculations may reason classically, while pure calculations have extractable computational content. Explicitly moving between the worlds of specification and implementation is enabled by our metatheory. To validate our approach, we provide two case studies in mechanizing existing proofs from the literature: the first uses calculational abstract interpretation to design a static analyzer; the second forms a semantic basis for gradual typing. Both mechanized proofs closely follow their original paper-and-pencil counterparts, employ reasoning principles not captured by previous mechanization approaches, support the extraction of verified algorithms, and are novel.

Published
2018
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23. Gradual Liquid Type Inference

Author

Vazou, Niki, Tanter, Éric, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Liquid typing provides a decidable refinement inference mechanism that is convenient but subject to two major issues: (1) inference is global and requires top-level annotations, making it unsuitable for inference of modular code components and prohibiting its applicability to library code, and (2) inference failure results in obscure error messages. These difficulties seriously hamper the migration of existing code to use refinements. This paper shows that gradual liquid type inference---a novel combination of liquid inference and gradual refinement types---addresses both issues. Gradual refinement types, which support imprecise predicates that are optimistically interpreted, can be used in argument positions to constrain liquid inference so that the global inference process e effectively infers modular specifications usable for library components. Dually, when gradual refinements appear as the result of inference, they signal an inconsistency in the use of static refinements. Because liquid refinements are drawn from a nite set of predicates, in gradual liquid type inference we can enumerate the safe concretizations of each imprecise refinement, i.e. the static refinements that justify why a program is gradually well-typed. This enumeration is useful for static liquid type error explanation, since the safe concretizations exhibit all the potential inconsistencies that lead to static type errors. We develop the theory of gradual liquid type inference and explore its pragmatics in the setting of Liquid Haskell., Comment: To appear at OOPSLA 2018

Published
2018
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24. Functional Pearl: Theorem Proving for All (Equational Reasoning in Liquid Haskell)

Author

Vazou, Niki, Breitner, Joachim, Kunkel, Will, Van Horn, David, and Hutton, Graham

Subjects
Computer Science - Programming Languages
Abstract

Equational reasoning is one of the key features of pure functional languages such as Haskell. To date, however, such reasoning always took place externally to Haskell, either manually on paper, or mechanised in a theorem prover. This article shows how equational reasoning can be performed directly and seamlessly within Haskell itself, and be checked using Liquid Haskell. In particular, language learners --- to whom external theorem provers are out of reach --- can benefit from having their proofs mechanically checked. Concretely, we show how the equational proofs and derivations from Graham's textbook can be recast as proofs in Haskell (spoiler: they look essentially the same)., Comment: Submitted to Haskell'18

Published
2018

26. Soft Contract Verification for Higher-Order Stateful Programs

Author

Nguyen, Phuc C., Gilray, Thomas, Tobin-Hochstadt, Sam, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Software contracts allow programmers to state rich program properties using the full expressive power of an object language. However, since they are enforced at runtime, monitoring contracts imposes significant overhead and delays error discovery. So contract verification aims to guarantee all or most of these properties ahead of time, enabling valuable optimizations and yielding a more general assurance of correctness. Existing methods for static contract verification satisfy the needs of more restricted target languages, but fail to address the challenges unique to those conjoining untyped, dynamic programming, higher-order functions, modularity, and statefulness. Our approach tackles all these features at once, in the context of the full Racket system---a mature environment for stateful, higher-order, multi-paradigm programming with or without types. Evaluating our method using a set of both pure and stateful benchmarks, we are able to verify 99.94% of checks statically (all but 28 of 49, 861). Stateful, higher-order functions pose significant challenges for static contract verification in particular. In the presence of these features, a modular analysis must permit code from the current module to escape permanently to an opaque context (unspecified code from outside the current module) that may be stateful and therefore store a reference to the escaped closure. Also, contracts themselves, being predicates wri en in unrestricted Racket, may exhibit stateful behavior; a sound approach must be robust to contracts which are arbitrarily expressive and interwoven with the code they monitor. In this paper, we present and evaluate our solution based on higher-order symbolic execution, explain the techniques we used to address such thorny issues, formalize a notion of behavioral approximation, and use it to provide a mechanized proof of soundness., Comment: ACM SIGPLAN Symposium on Principles of Programming Language (POPL)

Published
2017
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27. Abstracting Definitional Interpreters

Author

Darais, David, Labich, Nicholas, Nguyen, Phuc C., and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

In this functional pearl, we examine the use of definitional interpreters as a basis for abstract interpretation of higher-order programming languages. As it turns out, definitional interpreters, especially those written in monadic style, can provide a nice basis for a wide variety of collecting semantics, abstract interpretations, symbolic executions, and their intermixings. But the real insight of this story is a replaying of an insight from Reynold's landmark paper, Definitional Interpreters for Higher-Order Programming Languages, in which he observes definitional interpreters enable the defined-language to inherit properties of the defining-language. We show the same holds true for definitional abstract interpreters. Remarkably, we observe that abstract definitional interpreters can inherit the so-called "pushdown control flow" property, wherein function calls and returns are precisely matched in the abstract semantics, simply by virtue of the function call mechanism of the defining-language. The first approaches to achieve this property for higher-order languages appeared within the last ten years, and have since been the subject of many papers. These approaches start from a state-machine semantics and uniformly involve significant technical engineering to recover the precision of pushdown control flow. In contrast, starting from a definitional interpreter, the pushdown control flow property is inherent in the meta-language and requires no further technical mechanism to achieve.

Published
2017
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30. A Vision for Online Verification-Validation

Author

Hammer, Matthew A., Chang, Bor-Yuh Evan, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Today's programmers face a false choice between creating software that is extensible and software that is correct. Specifically, dynamic languages permit software that is richly extensible (via dynamic code loading, dynamic object extension, and various forms of reflection), and today's programmers exploit this flexibility to "bring their own language features" to enrich extensible languages (e.g., by using common JavaScript libraries). Meanwhile, such library-based language extensions generally lack enforcement of their abstractions, leading to programming errors that are complex to avoid and predict. To offer verification for this extensible world, we propose online verification-validation (OVV), which consists of language and VM design that enables a "phaseless" approach to program analysis, in contrast to the standard static-dynamic phase distinction. Phaseless analysis freely interposes abstract interpretation with concrete execution, allowing analyses to use dynamic (concrete) information to prove universal (abstract) properties about future execution. In this paper, we present a conceptual overview of OVV through a motivating example program that uses a hypothetical database library. We present a generic semantics for OVV, and an extension to this semantics that offers a simple gradual type system for the database library primitives. The result of instantiating this gradual type system in an OVV setting is a checker that can progressively type successive continuations of the program until a continuation is fully verified. To evaluate the proposed vision of OVV for this example, we implement the VM semantics (in Rust), and show that this design permits progressive typing in this manner.

Published
2016

33. Constructive Galois Connections: Taming the Galois Connection Framework for Mechanized Metatheory

Author

Darais, David and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Galois connections are a foundational tool for structuring abstraction in semantics and their use lies at the heart of the theory of abstract interpretation. Yet, mechanization of Galois connections remains limited to restricted modes of use, preventing their general application in mechanized metatheory and certified programming. This paper presents constructive Galois connections, a variant of Galois connections that is effective both on paper and in proof assistants; is complete with respect to a large subset of classical Galois connections; and enables more general reasoning principles, including the "calculational" style advocated by Cousot. To design constructive Galois connection we identify a restricted mode of use of classical ones which is both general and amenable to mechanization in dependently-typed functional programming languages. Crucial to our metatheory is the addition of monadic structure to Galois connections to control a "specification effect". Effectful calculations may reason classically, while pure calculations have extractable computational content. Explicitly moving between the worlds of specification and implementation is enabled by our metatheory. To validate our approach, we provide two case studies in mechanizing existing proofs from the literature: one uses calculational abstract interpretation to design a static analyzer, the other forms a semantic basis for gradual typing. Both mechanized proofs closely follow their original paper-and-pencil counterparts, employ reasoning principles not captured by previous mechanization approaches, support the extraction of verified algorithms, and are novel.

Published
2015

34. Higher-order symbolic execution for contract verification and refutation

Author

Nguyen, Phuc C., Tobin-Hochstadt, Sam, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

We present a new approach to automated reasoning about higher-order programs by endowing symbolic execution with a notion of higher-order, symbolic values. Our approach is sound and relatively complete with respect to a first-order solver for base type values. Therefore, it can form the basis of automated verification and bug-finding tools for higher-order programs. To validate our approach, we use it to develop and evaluate a system for verifying and refuting behavioral software contracts of components in a functional language, which we call soft contract verification. In doing so, we discover a mutually beneficial relation between behavioral contracts and higher-order symbolic execution. Our system uses higher-order symbolic execution, leveraging contracts as a source of symbolic values including unknown behavioral values, and employs an updatable heap of contract invariants to reason about flow-sensitive facts. Whenever a contract is refuted, it reports a concrete counterexample reproducing the error, which may involve solving for an unknown function. The approach is able to analyze first-class contracts, recursive data structures, unknown functions, and control-flow-sensitive refinements of values, which are all idiomatic in dynamic languages. It makes effective use of an off-the-shelf solver to decide problems without heavy encodings. The approach is competitive with a wide range of existing tools---including type systems, flow analyzers, and model checkers---on their own benchmarks. We have built a tool which analyzes programs written in Racket, and report on its effectiveness in verifying and refuting contracts., Comment: This paper unifies and expands upon the work presented in the papers "Soft contract verification" [arXiv:1307.6239], and "Relatively complete counterexamples for higher-order programs" [arXiv:1411.3967]. It also subsumes the work in the paper "Higher-order symbolic execution via contracts" [arXiv:1103.1362]

Published
2015

35. Mechanically Verified Calculational Abstract Interpretation

Author

Darais, David and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Calculational abstract interpretation, long advocated by Cousot, is a technique for deriving correct-by-construction abstract interpreters from the formal semantics of programming languages. This paper addresses the problem of deriving correct-by-verified-construction abstract interpreters with the use of a proof assistant. We identify several technical challenges to overcome with the aim of supporting verified calculational abstract interpretation that is faithful to existing pencil-and-paper proofs, supports calculation with Galois connections generally, and enables the extraction of verified static analyzers from these proofs. To meet these challenges, we develop a theory of Galois connections in monadic style that include a specification effect. Effectful calculations may reason classically, while pure calculations have extractable computational content. Moving between the worlds of specification and implementation is enabled by our metatheory. To validate our approach, we give the first mechanically verified proof of correctness for Cousot's "Calculational design of a generic abstract interpreter." Our proof "by calculus" closely follows the original paper-and-pencil proof and supports the extraction of a verified static analyzer.

Published
2015

36. Pushdown Control-Flow Analysis for Free

Author

Gilray, Thomas, Lyde, Steven, Adams, Michael D., Might, Matthew, and Van Horn, David

Subjects
Computer Science - Programming Languages, D.3.4
Abstract

Traditional control-flow analysis (CFA) for higher-order languages, whether implemented by constraint-solving or abstract interpretation, introduces spurious connections between callers and callees. Two distinct invocations of a function will necessarily pollute one another's return-flow. Recently, three distinct approaches have been published which provide perfect call-stack precision in a computable manner: CFA2, PDCFA, and AAC. Unfortunately, CFA2 and PDCFA are difficult to implement and require significant engineering effort. Furthermore, all three are computationally expensive; for a monovariant analysis, CFA2 is in $O(2^n)$, PDCFA is in $O(n^6)$, and AAC is in $O(n^9 log n)$. In this paper, we describe a new technique that builds on these but is both straightforward to implement and computationally inexpensive. The crucial insight is an unusual state-dependent allocation strategy for the addresses of continuation. Our technique imposes only a constant-factor overhead on the underlying analysis and, with monovariance, costs only O(n3) in the worst case. This paper presents the intuitions behind this development, a proof of the precision of this analysis, and benchmarks demonstrating its efficacy., Comment: in Proceedings of the 43rd Annual ACM SIGPLAN-SIGACT Symposium on Principles of Programming Languages, 2016

Published
2015
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37. Incremental Computation with Names

Author

Hammer, Matthew A., Dunfield, Jana, Headley, Kyle, Labich, Nicholas, Foster, Jeffrey S., Hicks, Michael, and Van Horn, David

Subjects
Computer Science - Programming Languages, D.3.1, D.3.3, F.3.2
Abstract

Over the past thirty years, there has been significant progress in developing general-purpose, language-based approaches to incremental computation, which aims to efficiently update the result of a computation when an input is changed. A key design challenge in such approaches is how to provide efficient incremental support for a broad range of programs. In this paper, we argue that first-class names are a critical linguistic feature for efficient incremental computation. Names identify computations to be reused across differing runs of a program, and making them first class gives programmers a high level of control over reuse. We demonstrate the benefits of names by presenting NOMINAL ADAPTON, an ML-like language for incremental computation with names. We describe how to use NOMINAL ADAPTON to efficiently incrementalize several standard programming patterns -- including maps, folds, and unfolds -- and show how to build efficient, incremental probabilistic trees and tries. Since NOMINAL ADAPTON's implementation is subtle, we formalize it as a core calculus and prove it is from-scratch consistent, meaning it always produces the same answer as simply re-running the computation. Finally, we demonstrate that NOMINAL ADAPTON can provide large speedups over both from-scratch computation and ADAPTON, a previous state-of-the-art incremental computation system., Comment: OOPSLA '15, October 25-30, 2015, Pittsburgh, PA, USA

Published
2015
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38. Running Probabilistic Programs Backwards

Author

Toronto, Neil, McCarthy, Jay, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Many probabilistic programming languages allow programs to be run under constraints in order to carry out Bayesian inference. Running programs under constraints could enable other uses such as rare event simulation and probabilistic verification---except that all such probabilistic languages are necessarily limited because they are defined or implemented in terms of an impoverished theory of probability. Measure-theoretic probability provides a more general foundation, but its generality makes finding computational content difficult. We develop a measure-theoretic semantics for a first-order probabilistic language with recursion, which interprets programs as functions that compute preimages. Preimage functions are generally uncomputable, so we derive an abstract semantics. We implement the abstract semantics and use the implementation to carry out Bayesian inference, stochastic ray tracing (a rare event simulation), and probabilistic verification of floating-point error bounds., Comment: 26 pages, ESOP 2015 (to appear)

Published
2014

42. Quantitative Analysis of Human Pluripotency and Neural Specification by In-Depth (Phospho)Proteomic Profiling

Author

Singec, Ilyas, Crain, Andrew M, Hou, Junjie, Tobe, Brian TD, Talantova, Maria, Winquist, Alicia A, Doctor, Kutbuddin S, Choy, Jennifer, Huang, Xiayu, La Monaca, Esther, Horn, David M, Wolf, Dieter A, Lipton, Stuart A, Gutierrez, Gustavo J, Brill, Laurence M, and Snyder, Evan Y

Subjects
Biochemistry and Cell Biology, Biological Sciences, Neurosciences, Stem Cell Research, Transplantation, Stem Cell Research - Embryonic - Non-Human, Stem Cell Research - Embryonic - Human, Regenerative Medicine, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Animals, Cell Differentiation, Cell Lineage, Cells, Cultured, Computational Biology, Gene Expression Profiling, Gene Knockdown Techniques, Humans, Neurons, Phosphoproteins, Pluripotent Stem Cells, Proteome, Proteomics, Signal Transduction, Transcriptome, Clinical Sciences, Biochemistry and cell biology
Abstract

Controlled differentiation of human embryonic stem cells (hESCs) can be utilized for precise analysis of cell type identities during early development. We established a highly efficient neural induction strategy and an improved analytical platform, and determined proteomic and phosphoproteomic profiles of hESCs and their specified multipotent neural stem cell derivatives (hNSCs). This quantitative dataset (nearly 13,000 proteins and 60,000 phosphorylation sites) provides unique molecular insights into pluripotency and neural lineage entry. Systems-level comparative analysis of proteins (e.g., transcription factors, epigenetic regulators, kinase families), phosphorylation sites, and numerous biological pathways allowed the identification of distinct signatures in pluripotent and multipotent cells. Furthermore, as predicted by the dataset, we functionally validated an autocrine/paracrine mechanism by demonstrating that the secreted protein midkine is a regulator of neural specification. This resource is freely available to the scientific community, including a searchable website, PluriProt.

Published
2016

43. Galois Transformers and Modular Abstract Interpreters

Author

Darais, David, Might, Matthew, and Van Horn, David

Subjects
Computer Science - Programming Languages, F.3.2
Abstract

The design and implementation of static analyzers has become increasingly systematic. Yet for a given language or analysis feature, it often requires tedious and error prone work to implement an analyzer and prove it sound. In short, static analysis features and their proofs of soundness do not compose well, causing a dearth of reuse in both implementation and metatheory. We solve the problem of systematically constructing static analyzers by introducing Galois transformers: monad transformers that transport Galois connection properties. In concert with a monadic interpreter, we define a library of monad transformers that implement building blocks for classic analysis parameters like context, path, and heap (in)sensitivity. Moreover, these can be composed together independent of the language being analyzed. Significantly, a Galois transformer can be proved sound once and for all, making it a reusable analysis component. As new analysis features and abstractions are developed and mixed in, soundness proofs need not be reconstructed, as the composition of a monad transformer stack is sound by virtue of its constituents. Galois transformers provide a viable foundation for reusable and composable metatheory for program analysis. Finally, these Galois transformers shift the level of abstraction in analysis design and implementation to a level where non-specialists have the ability to synthesize sound analyzers over a number of parameters., Comment: OOPSLA '15, October 25-30, 2015, Pittsburgh, PA, USA

Published
2014
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44. Relatively Complete Counterexamples for Higher-Order Programs

Author

Nguyen, Phuc C. and Van Horn, David

Subjects
Computer Science - Programming Languages, D.2.4, D.3.1
Abstract

In this paper, we study the problem of generating inputs to a higher-order program causing it to error. We first study the problem in the setting of PCF, a typed, core functional language and contribute the first relatively complete method for constructing counterexamples for PCF programs. The method is relatively complete in the sense of Hoare logic; completeness is reduced to the completeness of a first-order solver over the base types of PCF. In practice, this means an SMT solver can be used for the effective, automated generation of higher-order counterexamples for a large class of programs. We achieve this result by employing a novel form of symbolic execution for higher-order programs. The remarkable aspect of this symbolic execution is that even though symbolic higher-order inputs and values are considered, the path condition remains a first-order formula. Our handling of symbolic function application enables the reconstruction of higher-order counterexamples from this first-order formula. After establishing our main theoretical results, we sketch how to apply the approach to untyped, higher-order, stateful languages with first-class contracts and show how counterexample generation can be used to detect contract violations in this setting. To validate our approach, we implement a tool generating counterexamples for erroneous modules written in Racket., Comment: In Proceedings of the 36th annual ACM SIGPLAN conference on Programming Language Design and Implementation, Portland, Oregon, June 2015

Published
2014

46. Pruning, Pushdown Exception-Flow Analysis

Author

Liang, Shuying, Sun, Weibin, Might, Matthew, Keep, Andy, and Van Horn, David

Subjects
Computer Science - Programming Languages
Abstract

Statically reasoning in the presence of exceptions and about the effects of exceptions is challenging: exception-flows are mutually determined by traditional control-flow and points-to analyses. We tackle the challenge of analyzing exception-flows from two angles. First, from the angle of pruning control-flows (both normal and exceptional), we derive a pushdown framework for an object-oriented language with full-featured exceptions. Unlike traditional analyses, it allows precise matching of throwers to catchers. Second, from the angle of pruning points-to information, we generalize abstract garbage collection to object-oriented programs and enhance it with liveness analysis. We then seamlessly weave the techniques into enhanced reachability computation, yielding highly precise exception-flow analysis, without becoming intractable, even for large applications. We evaluate our pruned, pushdown exception-flow analysis, comparing it with an established analysis on large scale standard Java benchmarks. The results show that our analysis significantly improves analysis precision over traditional analysis within a reasonable analysis time., Comment: 14th IEEE International Working Conference on Source Code Analysis and Manipulation

Published
2014
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47. Pushdown flow analysis with abstract garbage collection

Author

Johnson, J. Ian, Sergey, Ilya, Earl, Christopher, Might, Matthew, and Van Horn, David

Subjects
Computer Science - Programming Languages, D.3.4, F.3.2
Abstract

In the static analysis of functional programs, pushdown flow analysis and abstract garbage collection push the boundaries of what we can learn about programs statically. This work illuminates and poses solutions to theoretical and practical challenges that stand in the way of combining the power of these techniques. Pushdown flow analysis grants unbounded yet computable polyvariance to the analysis of return-flow in higher-order programs. Abstract garbage collection grants unbounded polyvariance to abstract addresses which become unreachable between invocations of the abstract contexts in which they were created. Pushdown analysis solves the problem of precisely analyzing recursion in higher-order languages; abstract garbage collection is essential in solving the "stickiness" problem. Alone, our benchmarks demonstrate that each method can reduce analysis times and boost precision by orders of magnitude. We combine these methods. The challenge in marrying these techniques is not subtle: computing the reachable control states of a pushdown system relies on limiting access during transition to the top of the stack; abstract garbage collection, on the other hand, needs full access to the entire stack to compute a root set, just as concrete collection does. Conditional pushdown systems were developed for just such a conundrum, but existing methods are ill-suited for the dynamic nature of garbage collection. We show fully precise and approximate solutions to the feasible paths problem for pushdown garbage-collecting control-flow analysis. Experiments reveal synergistic interplay between garbage collection and pushdown techniques, and the fusion demonstrates "better-than-both-worlds" precision.

Published
2014
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49. Preclinical candidate for the treatment of visceral leishmaniasis that acts through proteasome inhibition

Author

Wyllie, Susan, Brand, Stephen, Thomas, Michael, De Rycker, Manu, Chung, Chun-wa, Pena, Imanol, Bingham, Ryan P., Bueren-Calabuig, Juan A., Cantizani, Juan, Cebrian, David, Craggs, Peter D., Ferguson, Liam, Goswami, Panchali, Hobrath, Judith, Howe, Jonathan, Jeacock, Laura, Ko, Eun-Jung, Korczynska, Justyna, MacLean, Lorna, Manthri, Sujatha, Martinez, Maria S., Mata-Cantero, Lydia, Moniz, Sonia, Nühs, Andrea, Osuna-Cabello, Maria, Pinto, Erika, Riley, Jennifer, Robinson, Sharon, Rowland, Paul, Simeons, Frederick R. C., Shishikura, Yoko, Spinks, Daniel, Stojanovski, Laste, Thomas, John, Thompson, Stephen, Gaza, Elisabet Viayna, Wall, Richard J., Zuccotto, Fabio, Horn, David, Ferguson, Michael A. J., Fairlamb, Alan H., Fiandor, Jose M., Martin, Julio, Gray, David W., Miles, Timothy J., Gilbert, Ian H., Read, Kevin D., Marco, Maria, and Wyatt, Paul G.

Published
2019

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