prime-numbers
Problem-solving strategies for prime numbers in graph number theory
Packaged view
This page reorganizes the original catalog entry around fit, installability, and workflow context first. The original raw source lives below.
Install command
npx @skill-hub/cli install parcadei-continuous-claude-v3-prime-numbers
Repository
Skill path: .claude/skills/math/graph-number-theory/prime-numbers
Problem-solving strategies for prime numbers in graph number theory
Open repositoryBest for
Primary workflow: Ship Full Stack.
Technical facets: Full Stack.
Target audience: everyone.
License: Unknown.
Original source
Catalog source: SkillHub Club.
Repository owner: parcadei.
This is still a mirrored public skill entry. Review the repository before installing into production workflows.
What it helps with
- Install prime-numbers into Claude Code, Codex CLI, Gemini CLI, or OpenCode workflows
- Review https://github.com/parcadei/Continuous-Claude-v3 before adding prime-numbers to shared team environments
- Use prime-numbers for development workflows
Works across
Favorites: 0.
Sub-skills: 0.
Aggregator: No.
Original source / Raw SKILL.md
---
name: prime-numbers
description: "Problem-solving strategies for prime numbers in graph number theory"
allowed-tools: [Bash, Read]
---
# Prime Numbers
## When to Use
Use this skill when working on prime-numbers problems in graph number theory.
## Decision Tree
1. **Primality testing hierarchy**
- Trial division: O(sqrt(n)), exact
- Miller-Rabin: O(k log^3 n), probabilistic
- AKS: O(log^6 n), deterministic polynomial
2. **Factorization**
- Trial division for small factors
- Pollard's rho: probabilistic, medium numbers
- Quadratic sieve: large numbers
- `sympy_compute.py factor "n"`
3. **Prime distribution**
- Prime Number Theorem: pi(x) ~ x/ln(x)
- Prime gaps: p_{n+1} - p_n
- `sympy_compute.py limit "pi(x) * ln(x) / x"`
4. **Fermat's Little Theorem**
- a^{p-1} = 1 (mod p) for a not divisible by p
- Use for modular exponentiation
- `z3_solve.py prove "fermat_little"`
5. **Wilson's Theorem**
- (p-1)! = -1 (mod p) iff p is prime
## Tool Commands
### Sympy_Factor
```bash
uv run python -m runtime.harness scripts/sympy_compute.py factor "n"
```
### Z3_Primality
```bash
uv run python -m runtime.harness scripts/z3_solve.py prove "no_divisor_between_1_and_sqrt_n"
```
### Sympy_Prime_Count
```bash
uv run python -m runtime.harness scripts/sympy_compute.py simplify "pi(x) ~ x/ln(x)"
```
### Z3_Fermat_Little
```bash
uv run python -m runtime.harness scripts/z3_solve.py prove "a**(p-1) == 1 mod p"
```
## Key Techniques
*From indexed textbooks:*
## Cognitive Tools Reference
See `.claude/skills/math-mode/SKILL.md` for full tool documentation.