constant-time-analysis

Detects timing side-channel vulnerabilities in cryptographic code. Use when implementing or reviewing crypto code, encountering division on secrets, secret-dependent branches, or constant-time programming questions in C, C++, Go, Rust, Swift, Java, Kotlin, C#, PHP, JavaScript, TypeScript, Python, or Ruby.

10 stars

Best use case

constant-time-analysis is best used when you need a repeatable AI agent workflow instead of a one-off prompt.

Detects timing side-channel vulnerabilities in cryptographic code. Use when implementing or reviewing crypto code, encountering division on secrets, secret-dependent branches, or constant-time programming questions in C, C++, Go, Rust, Swift, Java, Kotlin, C#, PHP, JavaScript, TypeScript, Python, or Ruby.

Teams using constant-time-analysis should expect a more consistent output, faster repeated execution, less prompt rewriting.

When to use this skill

  • You want a reusable workflow that can be run more than once with consistent structure.

When not to use this skill

  • You only need a quick one-off answer and do not need a reusable workflow.
  • You cannot install or maintain the underlying files, dependencies, or repository context.

Installation

Claude Code / Cursor / Codex

$curl -o ~/.claude/skills/constant-time-analysis/SKILL.md --create-dirs "https://raw.githubusercontent.com/Blurjp/ImagePrepMCP/main/.claude/skills/trailofbits-constant-time-analysis/skills/constant-time-analysis/SKILL.md"

Manual Installation

  1. Download SKILL.md from GitHub
  2. Place it in .claude/skills/constant-time-analysis/SKILL.md inside your project
  3. Restart your AI agent — it will auto-discover the skill

How constant-time-analysis Compares

Feature / Agentconstant-time-analysisStandard Approach
Platform SupportNot specifiedLimited / Varies
Context Awareness High Baseline
Installation ComplexityUnknownN/A

Frequently Asked Questions

What does this skill do?

Detects timing side-channel vulnerabilities in cryptographic code. Use when implementing or reviewing crypto code, encountering division on secrets, secret-dependent branches, or constant-time programming questions in C, C++, Go, Rust, Swift, Java, Kotlin, C#, PHP, JavaScript, TypeScript, Python, or Ruby.

Where can I find the source code?

You can find the source code on GitHub using the link provided at the top of the page.

Related Guides

SKILL.md Source

# Constant-Time Analysis

Analyze cryptographic code to detect operations that leak secret data through execution timing variations.

## When to Use

```text
User writing crypto code? ──yes──> Use this skill
         │
         no
         │
         v
User asking about timing attacks? ──yes──> Use this skill
         │
         no
         │
         v
Code handles secret keys/tokens? ──yes──> Use this skill
         │
         no
         │
         v
Skip this skill
```

**Concrete triggers:**

- User implements signature, encryption, or key derivation
- Code contains `/` or `%` operators on secret-derived values
- User mentions "constant-time", "timing attack", "side-channel", "KyberSlash"
- Reviewing functions named `sign`, `verify`, `encrypt`, `decrypt`, `derive_key`

## When NOT to Use

- Non-cryptographic code (business logic, UI, etc.)
- Public data processing where timing leaks don't matter
- Code that doesn't handle secrets, keys, or authentication tokens
- High-level API usage where timing is handled by the library

## Language Selection

Based on the file extension or language context, refer to the appropriate guide:

| Language   | File Extensions                   | Guide                                                    |
| ---------- | --------------------------------- | -------------------------------------------------------- |
| C, C++     | `.c`, `.h`, `.cpp`, `.cc`, `.hpp` | [references/compiled.md](references/compiled.md)         |
| Go         | `.go`                             | [references/compiled.md](references/compiled.md)         |
| Rust       | `.rs`                             | [references/compiled.md](references/compiled.md)         |
| Swift      | `.swift`                          | [references/swift.md](references/swift.md)               |
| Java       | `.java`                           | [references/vm-compiled.md](references/vm-compiled.md)   |
| Kotlin     | `.kt`, `.kts`                     | [references/kotlin.md](references/kotlin.md)             |
| C#         | `.cs`                             | [references/vm-compiled.md](references/vm-compiled.md)   |
| PHP        | `.php`                            | [references/php.md](references/php.md)                   |
| JavaScript | `.js`, `.mjs`, `.cjs`             | [references/javascript.md](references/javascript.md)     |
| TypeScript | `.ts`, `.tsx`                     | [references/javascript.md](references/javascript.md)     |
| Python     | `.py`                             | [references/python.md](references/python.md)             |
| Ruby       | `.rb`                             | [references/ruby.md](references/ruby.md)                 |

## Quick Start

```bash
# Analyze any supported file type
uv run {baseDir}/ct_analyzer/analyzer.py <source_file>

# Include conditional branch warnings
uv run {baseDir}/ct_analyzer/analyzer.py --warnings <source_file>

# Filter to specific functions
uv run {baseDir}/ct_analyzer/analyzer.py --func 'sign|verify' <source_file>

# JSON output for CI
uv run {baseDir}/ct_analyzer/analyzer.py --json <source_file>
```

### Native Compiled Languages Only (C, C++, Go, Rust)

```bash
# Cross-architecture testing (RECOMMENDED)
uv run {baseDir}/ct_analyzer/analyzer.py --arch x86_64 crypto.c
uv run {baseDir}/ct_analyzer/analyzer.py --arch arm64 crypto.c

# Multiple optimization levels
uv run {baseDir}/ct_analyzer/analyzer.py --opt-level O0 crypto.c
uv run {baseDir}/ct_analyzer/analyzer.py --opt-level O3 crypto.c
```

### VM-Compiled Languages (Java, Kotlin, C#)

```bash
# Analyze Java bytecode
uv run {baseDir}/ct_analyzer/analyzer.py CryptoUtils.java

# Analyze Kotlin bytecode (Android/JVM)
uv run {baseDir}/ct_analyzer/analyzer.py CryptoUtils.kt

# Analyze C# IL
uv run {baseDir}/ct_analyzer/analyzer.py CryptoUtils.cs
```

Note: Java, Kotlin, and C# compile to bytecode (JVM/CIL) that runs on a virtual machine with JIT compilation. The analyzer examines the bytecode directly, not the JIT-compiled native code. The `--arch` and `--opt-level` flags do not apply to these languages.

### Swift (iOS/macOS)

```bash
# Analyze Swift for native architecture
uv run {baseDir}/ct_analyzer/analyzer.py crypto.swift

# Analyze for specific architecture (iOS devices)
uv run {baseDir}/ct_analyzer/analyzer.py --arch arm64 crypto.swift

# Analyze with different optimization levels
uv run {baseDir}/ct_analyzer/analyzer.py --opt-level O0 crypto.swift
```

Note: Swift compiles to native code like C/C++/Go/Rust, so it uses assembly-level analysis and supports `--arch` and `--opt-level` flags.

### Prerequisites

| Language               | Requirements                                              |
| ---------------------- | --------------------------------------------------------- |
| C, C++, Go, Rust       | Compiler in PATH (`gcc`/`clang`, `go`, `rustc`)           |
| Swift                  | Xcode or Swift toolchain (`swiftc` in PATH)               |
| Java                   | JDK with `javac` and `javap` in PATH                      |
| Kotlin                 | Kotlin compiler (`kotlinc`) + JDK (`javap`) in PATH       |
| C#                     | .NET SDK + `ilspycmd` (`dotnet tool install -g ilspycmd`) |
| PHP                    | PHP with VLD extension or OPcache                         |
| JavaScript/TypeScript  | Node.js in PATH                                           |
| Python                 | Python 3.x in PATH                                        |
| Ruby                   | Ruby with `--dump=insns` support                          |

**macOS users**: Homebrew installs Java and .NET as "keg-only". You must add them to your PATH:

```bash
# For Java (add to ~/.zshrc)
export PATH="/opt/homebrew/opt/openjdk@21/bin:$PATH"

# For .NET tools (add to ~/.zshrc)
export PATH="$HOME/.dotnet/tools:$PATH"
```

See [references/vm-compiled.md](references/vm-compiled.md) for detailed setup instructions and troubleshooting.

## Quick Reference

| Problem                | Detection                       | Fix                                          |
| ---------------------- | ------------------------------- | -------------------------------------------- |
| Division on secrets    | DIV, IDIV, SDIV, UDIV           | Barrett reduction or multiply-by-inverse     |
| Branch on secrets      | JE, JNE, BEQ, BNE               | Constant-time selection (cmov, bit masking)  |
| Secret comparison      | Early-exit memcmp               | Use `crypto/subtle` or constant-time compare |
| Weak RNG               | rand(), mt_rand, Math.random    | Use crypto-secure RNG                        |
| Table lookup by secret | Array subscript on secret index | Bit-sliced lookups                           |

## Interpreting Results

**PASSED** - No variable-time operations detected.

**FAILED** - Dangerous instructions found. Example:

```text
[ERROR] SDIV
  Function: decompose_vulnerable
  Reason: SDIV has early termination optimization; execution time depends on operand values
```

## Verifying Results (Avoiding False Positives)

**CRITICAL**: Not every flagged operation is a vulnerability. The tool has no data flow analysis - it flags ALL potentially dangerous operations regardless of whether they involve secrets.

For each flagged violation, ask: **Does this operation's input depend on secret data?**

1. **Identify the secret inputs** to the function (private keys, plaintext, signatures, tokens)

2. **Trace data flow** from the flagged instruction back to inputs

3. **Common false positive patterns**:

   ```c
   // FALSE POSITIVE: Division uses public constant, not secret
   int num_blocks = data_len / 16;  // data_len is length, not content

   // TRUE POSITIVE: Division involves secret-derived value
   int32_t q = secret_coef / GAMMA2;  // secret_coef from private key
   ```

4. **Document your analysis** for each flagged item

### Quick Triage Questions

| Question                                          | If Yes                | If No                 |
| ------------------------------------------------- | --------------------- | --------------------- |
| Is the operand a compile-time constant?           | Likely false positive | Continue              |
| Is the operand a public parameter (length, count)?| Likely false positive | Continue              |
| Is the operand derived from key/plaintext/secret? | **TRUE POSITIVE**     | Likely false positive |
| Can an attacker influence the operand value?      | **TRUE POSITIVE**     | Likely false positive |

## Limitations

1. **Static Analysis Only**: Analyzes assembly/bytecode, not runtime behavior. Cannot detect cache timing or microarchitectural side-channels.

2. **No Data Flow Analysis**: Flags all dangerous operations regardless of whether they process secrets. Manual review required.

3. **Compiler/Runtime Variations**: Different compilers, optimization levels, and runtime versions may produce different output.

## Real-World Impact

- **KyberSlash (2023)**: Division instructions in post-quantum ML-KEM implementations allowed key recovery
- **Lucky Thirteen (2013)**: Timing differences in CBC padding validation enabled plaintext recovery
- **RSA Timing Attacks**: Early implementations leaked private key bits through division timing

## References

- [Cryptocoding Guidelines](https://github.com/veorq/cryptocoding) - Defensive coding for crypto
- [KyberSlash](https://kyberslash.cr.yp.to/) - Division timing in post-quantum crypto
- [BearSSL Constant-Time](https://www.bearssl.org/constanttime.html) - Practical constant-time techniques

Related Skills

variant-analysis

10
from Blurjp/ImagePrepMCP

Find similar vulnerabilities and bugs across codebases using pattern-based analysis. Use when hunting bug variants, building CodeQL/Semgrep queries, analyzing security vulnerabilities, or performing systematic code audits after finding an initial issue.

coverage-analysis

10
from Blurjp/ImagePrepMCP

Coverage analysis measures code exercised during fuzzing. Use when assessing harness effectiveness or identifying fuzzing blockers.

constant-time-testing

10
from Blurjp/ImagePrepMCP

Constant-time testing detects timing side channels in cryptographic code. Use when auditing crypto implementations for timing vulnerabilities.

statistical-analysis

10
from Blurjp/ImagePrepMCP

Guided statistical analysis with test selection and reporting. Use when you need help choosing appropriate tests for your data, assumption checking, power analysis, and APA-formatted results. Best for academic research reporting, test selection guidance. For implementing specific models programmatically use statsmodels.

neuropixels-analysis

10
from Blurjp/ImagePrepMCP

Neuropixels neural recording analysis. Load SpikeGLX/OpenEphys data, preprocess, motion correction, Kilosort4 spike sorting, quality metrics, Allen/IBL curation, AI-assisted visual analysis, for Neuropixels 1.0/2.0 extracellular electrophysiology. Use when working with neural recordings, spike sorting, extracellular electrophysiology, or when the user mentions Neuropixels, SpikeGLX, Open Ephys, Kilosort, quality metrics, or unit curation.

exploratory-data-analysis

10
from Blurjp/ImagePrepMCP

Perform comprehensive exploratory data analysis on scientific data files across 200+ file formats. This skill should be used when analyzing any scientific data file to understand its structure, content, quality, and characteristics. Automatically detects file type and generates detailed markdown reports with format-specific analysis, quality metrics, and downstream analysis recommendations. Covers chemistry, bioinformatics, microscopy, spectroscopy, proteomics, metabolomics, and general scientific data formats.

webapp-testing

10
from Blurjp/ImagePrepMCP

Toolkit for interacting with and testing local web applications using Playwright. Supports verifying frontend functionality, debugging UI behavior, capturing browser screenshots, and viewing browser logs.

web-asset-generator

10
from Blurjp/ImagePrepMCP

Generate web assets including favicons, app icons (PWA), and social media meta images (Open Graph) for Facebook, Twitter, WhatsApp, and LinkedIn. Use when users need icons, favicons, social sharing images, or Open Graph images from logos or text slogans. Handles image resizing, text-to-image generation, and provides proper HTML meta tags.

web-artifacts-builder

10
from Blurjp/ImagePrepMCP

Suite of tools for creating elaborate, multi-component claude.ai HTML artifacts using modern frontend web technologies (React, Tailwind CSS, shadcn/ui). Use for complex artifacts requiring state management, routing, or shadcn/ui components - not for simple single-file HTML/JSX artifacts.

wycheproof

10
from Blurjp/ImagePrepMCP

Wycheproof provides test vectors for validating cryptographic implementations. Use when testing crypto code for known attacks and edge cases.

testing-handbook-generator

10
from Blurjp/ImagePrepMCP

Meta-skill that analyzes the Trail of Bits Testing Handbook (appsec.guide) and generates Claude Code skills for security testing tools and techniques. Use when creating new skills based on handbook content.

ruzzy

10
from Blurjp/ImagePrepMCP

Ruzzy is a coverage-guided Ruby fuzzer by Trail of Bits. Use for fuzzing pure Ruby code and Ruby C extensions.