Top of the Heap: Efficient Memory Error Protection of Safe Heap Objects

Heap memory errors remain a major source of software vulnerabilities. Existing memory safety defenses aim at protecting all objects, resulting in high performance cost and incomplete protection. Instead, we propose an approach that accurately identifies objects that are inexpensive to protect, and design a method to protect such objects comprehensively from all classes of memory errors. Towards this goal, we introduce the Uriah system that (1) statically identifies the heap objects whose accesses satisfy spatial and type safety, and (2) dynamically allocates such "safe" heap objects on an isolated safe heap to enforce a form of temporal safety while preserving spatial and type safety, called temporal allocated-type safety. Uriah finds 72.0% of heap allocation sites produce objects whose accesses always satisfy spatial and type safety in the SPEC CPU2006/2017 benchmarks, 5 server programs, and Firefox, which are then isolated on a safe heap using Uriah allocator to enforce temporal allocated-type safety. Uriah incurs only 2.9% and 2.6% runtime overhead, along with 9.3% and 5.4% memory overhead, on the SPEC CPU 2006 and 2017 benchmarks, while preventing exploits on all the heap memory errors in DARPA CGC binaries and 28 recent CVEs. Additionally, using existing defenses to enforce their memory safety guarantees on the unsafe heap objects significantly reduces overhead, enabling the protection of heap objects from all classes of memory errors at more practical costs.

• Publication year

  2023

• Venue

  Conference on Computer and Communications Security

• Publication date

  2023-10-10

• Fields of study

  Computer Science

• Identifiers
  DOI 10.1145/3658644.3690310arXiv 2310.06397
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar

• No claims are published for this paper.

• No concepts are published for this paper.

• K-LEAK: Towards Automating the Generation of Multi-Step Infoleak Exploits against the Linux Kernel

  2024cited by this paper
• CAMP: Compiler and Allocator-based Heap Memory Protection

  2024influential reference
• Don't Waste My Efforts: Pruning Redundant Sanitizer Checks by Developer-Implemented Type Checks

  2024cited by this paper
• Comprehensive Memory Safety Validation: An Alternative Approach to Memory Safety

  2024cited by this paper
• SyzBridge: Bridging the Gap in Exploitability Assessment of Linux Kernel Bugs in the Linux Ecosystem

  2024cited by this paper
• Assessing the Impact of Efficiently Protecting Ten Million Stack Objects from Memory Errors Comprehensively

  2023cited by this paper
• A Hybrid Alias Analysis and Its Application to Global Variable Protection in the Linux Kernel

  2023cited by this paper
• Cryptographically Enforced Memory Safety

  2023cited by this paper
• Top of the Heap: Efficient Memory Error Protection for Many Heap Objects

  2023cited by this paper
• PACMAN: Attacking ARM Pointer Authentication With Speculative Execution

  2022cited by this paper
• The Taming of the Stack: Isolating Stack Data from Memory Errors

  2022influential reference
• DirtyCred: Escalating Privilege in Linux Kernel

  2022cited by this paper
• PACMem: Enforcing Spatial and Temporal Memory Safety via ARM Pointer Authentication

  2022cited by this paper
• Fat Pointers for Temporal Memory Safety of C

  2022cited by this paper
• Mitigating Information Leakage Vulnerabilities with Type-based Data Isolation

  2022influential reference
• GREBE: Unveiling Exploitation Potential for Linux Kernel Bugs

  2022cited by this paper
• A systematic evaluation of large language models of code

  2022cited by this paper
• SyzScope: Revealing High-Risk Security Impacts of Fuzzer-Exposed Bugs in Linux kernel

  2021cited by this paper
• MAZE: Towards Automated Heap Feng Shui

  2021cited by this paper
• Asleep at the Keyboard? Assessing the Security of GitHub Copilot’s Code Contributions

  2021cited by this paper
• Cryptographic Capability Computing

  2021cited by this paper
• DynPTA: Combining Static and Dynamic Analysis for Practical Selective Data Protection

  2021cited by this paper
• Exploitation Techniques for Data-oriented Attacks with Existing and Potential Defense Approaches

  2021cited by this paper
• In-fat pointer: hardware-assisted tagged-pointer spatial memory safety defense with subobject granularity protection

  2021cited by this paper
• Preventing Use-After-Free Attacks with Fast Forward Allocation

  2021cited by this paper
• CrypTag: Thwarting Physical and Logical Memory Vulnerabilities using Cryptographically Colored Memory

  2020cited by this paper
• UBITect: a precise and scalable method to detect use-before-initialization bugs in Linux kernel

  2020cited by this paper
• Scalable Static Detection of Use-After-Free Vulnerabilities in Binary Code

  2020cited by this paper
• CHEx86: Context-Sensitive Enforcement of Memory Safety via Microcode-Enabled Capabilities

  2020cited by this paper
• MarkUs: Drop-in use-after-free prevention for low-level languages

  2020cited by this paper
• xMP: Selective Memory Protection for Kernel and User Space

  2020cited by this paper
• Value-Flow-Based Demand-Driven Pointer Analysis for C and C++

  2020cited by this paper
• Flow-Sensitive Type-Based Heap Cloning

  2020cited by this paper
• A Systematic Study of Elastic Objects in Kernel Exploitation

  2020cited by this paper
• Hardware-based Always-On Heap Memory Safety

  2020cited by this paper
• Using Safety Properties to Generate Vulnerability Patches

  2019influential reference
• KEPLER: Facilitating Control-flow Hijacking Primitive Evaluation for Linux Kernel Vulnerabilities

  2019cited by this paper
• ARM Memory Tagging Extension and How It Improves C/C++ Memory Safety

  2019cited by this paper
• SLAKE: Facilitating Slab Manipulation for Exploiting Vulnerabilities in the Linux Kernel

  2019cited by this paper
• Memory Categorization: Separating Attacker-Controlled Data

  2019cited by this paper
• Language Models are Unsupervised Multitask Learners

  2019cited by this paper
• Checked C: Making C Safe by Extension

  2018cited by this paper
• Practical Memory Safety with REST

  2018cited by this paper
• Block Oriented Programming: Automating Data-Only Attacks

  2018cited by this paper
• Defensive Points-To Analysis: Effective Soundness via Laziness

  2018cited by this paper
• Spatio-Temporal Context Reduction: A Pointer-Analysis-Based Static Approach for Detecting Use-After-Free Vulnerabilities

  2018cited by this paper
• FUZE: Towards Facilitating Exploit Generation for Kernel Use-After-Free Vulnerabilities

  2018cited by this paper
• PAC it up: Towards Pointer Integrity using ARM Pointer Authentication

  2018cited by this paper
• Type-After-Type: Practical and Complete Type-Safe Memory Reuse

  2018influential reference
• Two Approaches to Interprocedural Data Flow Analysis

  2018cited by this paper
• FreeGuard: A Faster Secure Heap Allocator

  2017cited by this paper
• HexType: Efficient Detection of Type Confusion Errors for C++

  2017cited by this paper
• Safelnit: Comprehensive and Practical Mitigation of Uninitialized Read Vulnerabilities

  2017influential reference
• PtrSplit: Supporting General Pointers in Automatic Program Partitioning

  2017cited by this paper
• Memory Safety for Embedded Devices with nesCheck

  2017cited by this paper
• Machine-Learning-Guided Typestate Analysis for Static Use-After-Free Detection

  2017cited by this paper
• EffectiveSan: type and memory error detection using dynamically typed C/C++

  2017cited by this paper
• Stack Bounds Protection with Low Fat Pointers

  2017cited by this paper
• Control-Flow Integrity

  2017cited by this paper
• Heap bounds protection with low fat pointers

  2016cited by this paper
• Nginx

  2016cited by this paper
• Data-Oriented Programming: On the Expressiveness of Non-control Data Attacks

  2016cited by this paper
• Driller: Augmenting Fuzzing Through Selective Symbolic Execution

  2016cited by this paper
• Sparse flow-sensitive pointer analysis for multithreaded programs

  2016cited by this paper
• On-demand strong update analysis via value-flow refinement

  2016cited by this paper
• TypeSan: Practical Type Confusion Detection

  2016cited by this paper
• SVF: interprocedural static value-flow analysis in LLVM

  2016cited by this paper
• Type Casting Verification: Stopping an Emerging Attack Vector

  2015cited by this paper
• FreeSentry: protecting against use-after-free vulnerabilities due to dangling pointers

  2015cited by this paper
• Readactor: Practical Code Randomization Resilient to Memory Disclosure

  2015cited by this paper
• Preventing Use-after-free with Dangling Pointers Nullification

  2015cited by this paper
• Statically detecting use after free on binary code

  2014cited by this paper
• Code-pointer integrity

  2014cited by this paper
• POSTER: UAFChecker: Scalable Static Detection of Use-After-Free Vulnerabilities

  2014cited by this paper
• Detecting Memory Leaks Statically with Full-Sparse Value-Flow Analysis

  2014cited by this paper
• Static memory leak detection using full-sparse value-flow analysis

  2012cited by this paper
• Return-Oriented Programming: Systems, Languages, and Applications

  2012cited by this paper
• Anna Karenina

  2011cited by this paper
• S2E: a platform for in-vivo multi-path analysis of software systems

  2011cited by this paper
• The Design and Implementation of a Non-Iterative Range Analysis Algorithm on a Production Compiler

  2011cited by this paper
• Heap cloning: Enabling dynamic symbolic execution of java programs

  2011cited by this paper
• Intel ® Guide for Developing Multithreaded Applications Part 1 : Application Threading and Synchronization Summary

  2010cited by this paper
• DieHarder: securing the heap

  2010cited by this paper
• Cling: A Memory Allocator to Mitigate Dangling Pointers

  2010cited by this paper
• MemSafe: Ensuring the Spatial and Temporal Memory Safety of C at Runtime

  2010cited by this paper
• CETS: compiler enforced temporal safety for C

  2010cited by this paper
• SoftBound: highly compatible and complete spatial memory safety for c

  2009cited by this paper
• Baggy Bounds Checking: An Efficient and Backwards-Compatible Defense against Out-of-Bounds Errors

  2009cited by this paper
• Value-Range Analysis of C Programs: Towards Proving the Absence of Buffer Overflow Vulnerabilities

  2008cited by this paper
• Engineering Heap Overflow Exploits with JavaScript

  2008cited by this paper
• Making context-sensitive points-to analysis with heap cloning practical for the real world

  2007cited by this paper
• DieHard: probabilistic memory safety for unsafe languages

  2006cited by this paper
• google,我,萨娜

  2006cited by this paper
• CCured: type-safe retrofitting of legacy software

  2005cited by this paper
• Non-Control-Data Attacks Are Realistic Threats

  2005cited by this paper
• SAFECode: enforcing alias analysis for weakly typed languages

  2005influential reference
• RETROSPECTIVE : A Safe Approximate Algorithm for Interprocedural Pointer Aliasing

  2004cited by this paper
• Cloning-based context-sensitive pointer alias analysis using binary decision diagrams

  2004cited by this paper
• CCured in the real world

  2003cited by this paper
• Address Obfuscation: An Efficient Approach to Combat a Broad Range of Memory Error Exploits

  2003cited by this paper

• Patch-to-PoC: A Systematic Study of Agentic LLM Systems for Linux Kernel N-Day Reproduction

  2026cites this paper
• SoK: Challenges and Paths Toward Memory Safety for eBPF

  2025influential citation
• Beyond Driver Isolation - Triaging Threats against Driver Isolation

  2025cites this paper
• QuickSafe: Targeted Hardening Against Memory Corruption

  year unknowncites this paper