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• Misconceptions In Finite-Trace and Infinite-Trace Linear Temporal Logic
• Iterative Student Program Planning using Transformer-Driven Feedback
• Differential Analysis: A Summary
• Forge: A Tool to Teach Formal Methods
• Finding and Fixing Standard Misconceptions About Program Behavior
• Privacy-Respecting Type Error Telemetry at Scale
• Profiling Programming Language Learning
• The Examplar Project: A Summary
• A Core Calculus for Documents
• Observations on the Design of Program Planning Notations for Students
• Conceptual Mutation Testing
• Generating Programs Trivially: Student Use of Large Language Models
• A Grounded Conceptual Model for Ownership Types in Rust
• What Happens When Students Switch (Functional) Languages
• Typed-Untyped Interactions: A Comparative Analysis
• Little Tricky Logics
• Identifying Problem Misconceptions
• Performance Preconceptions
• Structural Versus Pipeline Composition of Higher-Order Functions
• Plan Composition Using Higher-Order Functions
• Towards a Notional Machine for Runtime Stacks and Scope
• Gradual Soundness: Lessons from Static Python
• Applying Cognitive Principles to Model-Finding Output
• Automated, Targeted Testing of Property-Based Testing Predicates
• A Benchmark for Tabular Types
• Student Help-Seeking for (Un)Specified Behaviors
• Adding Function Transformers to CODAP
• Developing Behavioral Concepts of Higher-Order Functions
• Adversarial Thinking Early in Post-Secondary Education
• Teaching and Assessing Property-Based Testing
• Students Testing Without Coercion
• Using Design Alternatives to Learn About Data Organizations
• What Help Do Students Seek in TA Office Hours?
• Combating Misconceptions by Encouraging Example-Writing
• The Hidden Perils of Automated Assessment
• Mystery Languages
• Resugaring Type Rules
• Picking Colors for Pyret Error Messages
• Can We Crowdsource Language Design?
• Crowdsourcing User Studies for Formal Methods
• User Studies of Principled Model Finder Output
• A Third Perspective on Hygiene
• Scope Inference, a.k.a. Resugaring Scope Rules
• The PerMission Store
• Examining the Privacy Decisions Facing Users
• The Pyret Programming Language: Why Pyret?
• Resugaring Evaluation Sequences
• Slimming Languages by Reducing Sugar
• In-flow Peer Review: An Overview
• Tierless Programming for SDNs: Differential Analysis
• Tierless Programming for SDNs: Verification
• Tierless Programming for SDNs: Optimality
• Tierless Programming for SDNs: Events
• Tierless Programming for Software-Defined Networks
• CS Student Work/Sleep Habits Revealed As Possibly Dangerously Normal
• Parley: User Studies for Syntax Design
• Typechecking Uses of the jQuery Language
• Verifying Extensions’ Compliance with Firefox's Private Browsing Mode
• From MOOC Students to Researchers
• Social Ratings of Application Permissions (Part 4: The Goal)
• Social Ratings of Application Permissions (Part 3: Permissions Within a Domain)
• Social Ratings of Application Permissions (Part 2: The Effect of Branding)
• Social Ratings of Application Permissions (Part 1: Some Basic Conditions)
• Aluminum: Principled Scenario Exploration Through Minimality
• A Privacy-Affecting Change in Firefox 20
• The New MOOR's Law
• Essentials of Garbage Collection
• (Sub)Typing First Class Field Names
• Typing First Class Field Names
• S5: Engineering Eval
• Progressive Types
• Modeling DOM Events
• Mechanized LambdaJS
• ECMA Announces Official λJS Adoption
• Objects in Scripting Languages
• S5: Wat?
• Belay Lessons: Smarter Web Programming
• S5: Semantics for Accessors
• S5: A Semantics for Today's JavaScript
• The Essence of JavaScript
• ADsafety

Misconceptions In Finite-Trace and Infinite-Trace Linear Temporal Logic

Over the past three years and with a multi-national group of collaborators, we have been digging deeper into misconceptions in LTL (Linear Temporal Logic) and studying misconceptions in LTLf, a promising variant of LTL restricted to finite traces. Why LTL and LTLf? Because beyond their traditional uses in verification and now robot synthesis, they support even more applications, from image processing to web-page testing to process-rule mining. Why study misconceptions? Because ultimately, human users need to fully understand what a formula says before they can safely apply synthesis tools and the like.

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Iterative Student Program Planning using Transformer-Driven Feedback

We’ve had a few projects now that address this idea of teaching students to plan out solutions to programming problems. A thus-far missing but critical piece is feedback on this planning process. Ideally we want to give students feedback on their plans before they commit to any code details. Our early studies had students express their plans in a semi-formalized way which would’ve allowed us to automatically generate feedback based on formal structure. However, our most recent project highlighted a strong preference towards more freedom in notation, with plans expressed in far less structured language. This presents a challenge when designing automated feedback.

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Differential Analysis: A Summary

For multiple decades we have worked on a the problem of differential analysis. This post explains where it comes from, what it means, and what its consequences are.

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Forge: A Tool to Teach Formal Methods

For the past decade we have been studying how best to get students into formal methods (FM). Our focus is not on the 10% or so of students who will automatically gravitate towards it, but on the “other 90%” who don’t view it as a fundamental part of their existence (or of the universe). In particular, we decided to infuse FM thinking into the students who go off to build systems. Hence the course, Logic for Systems.

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Finding and Fixing Standard Misconceptions About Program Behavior

A large number of modern languages — from Java and C# to Python and JavaScript to Racket and OCaml — share a common semantic core:

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