analyze-prime-numbers
О программе
Этот навык предоставляет алгоритмы для анализа простых чисел, включая проверки на простоту, факторизацию и расчёты распределения. Он реализует такие методы, как Миллера–Рабина, пробное деление и решето Эратосфена для задач вроде проверки чисел на простоту, поиска делителей или вывода простых чисел в заданных пределах. Используйте его для теоретико-числовых вычислений, доказательств или любых задач разработки, требующих операций с простыми числами.
Быстрая установка
Claude Code
Рекомендуетсяnpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/analyze-prime-numbersСкопируйте и вставьте эту команду в Claude Code для установки этого навыка
Документация
Analyze Prime Numbers
Analyze prime numbers by selecting and applying the appropriate algorithm for the task at hand: primality testing, integer factorization, or prime distribution analysis. Verify results computationally and relate findings to the Prime Number Theorem.
When to Use
- Determining whether a given integer is prime or composite
- Finding the complete prime factorization of an integer
- Counting or listing primes up to a given bound
- Verifying the Prime Number Theorem approximation for a specific range
- Investigating properties of primes in a number-theoretic proof or computation
Inputs
- Required: The integer(s) to analyze, or a bound for distribution analysis
- Required: Task type -- one of: primality test, factorization, or distribution analysis
- Optional: Preferred algorithm (trial division, Miller-Rabin, Sieve of Eratosthenes, Pollard's rho)
- Optional: Whether to produce a formal proof of primality or a computational verdict
- Optional: Output format (factor tree, prime list, count, table)
Procedure
Step 1: Determine the Task Type
Classify the request into one of three categories and select the appropriate algorithmic path.
- Primality test: Given a single integer n, determine whether n is prime.
- Factorization: Given a composite integer n, find its complete prime factorization.
- Distribution analysis: Given a bound N, analyze the primes up to N (count, list, gaps, density).
Record the task type and the input value(s).
Got: A clear classification with the input values recorded.
If fail: If the input is ambiguous (e.g., "analyze 60"), ask the user to clarify whether they want a primality test, factorization, or distribution analysis. Default to factorization for composite numbers and primality confirmation for suspected primes.
Step 2: Apply Primality Testing (if task = primality)
Test whether n is prime using an algorithm matched to the size of n.
-
Handle trivial cases: n < 2 is not prime. n = 2 or n = 3 is prime. If n is even and n > 2, it is composite.
-
Small n (n < 10^6): Use trial division.
- Test divisibility by all primes p up to floor(sqrt(n)).
- Optimization: test 2, then odd numbers 3, 5, 7, ... or use a 6k +/- 1 wheel.
- If no divisor found, n is prime.
-
Large n (n >= 10^6): Use Miller-Rabin probabilistic test.
- Write n - 1 = 2^s * d where d is odd.
- For each witness a in {2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37}:
- Compute x = a^d mod n.
- If x = 1 or x = n - 1, this witness passes.
- Otherwise, square x up to s - 1 times. If x ever equals n - 1, pass.
- If no pass, n is composite (a is a witness).
- For n < 3.317 * 10^24, the witnesses {2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37} give a deterministic result.
-
Record the verdict: prime or composite, with the witness or certificate.
Small primes reference (first 25):
| Index | Prime | Index | Prime | Index | Prime |
|---|---|---|---|---|---|
| 1 | 2 | 10 | 29 | 19 | 67 |
| 2 | 3 | 11 | 31 | 20 | 71 |
| 3 | 5 | 12 | 37 | 21 | 73 |
| 4 | 7 | 13 | 41 | 22 | 79 |
| 5 | 11 | 14 | 43 | 23 | 83 |
| 6 | 13 | 15 | 47 | 24 | 89 |
| 7 | 17 | 16 | 53 | 25 | 97 |
| 8 | 19 | 17 | 59 | ||
| 9 | 23 | 18 | 61 |
Got: A definitive answer (prime or composite) with the algorithm used and any witnesses or divisors found.
If fail: If Miller-Rabin reports "probably prime" but certainty is required, escalate to a deterministic test (e.g., AKS or ECPP). For trial division, if computation is too slow, switch to Miller-Rabin.
Step 3: Apply Factorization (if task = factorization)
Factor n completely into its prime power decomposition.
-
Extract small factors by trial division:
- Divide out 2 as many times as possible, recording the exponent.
- Divide out odd primes 3, 5, 7, 11, ... up to a cutoff (e.g., 10^4 or sqrt(n) if n is small).
- After each division, update n to the remaining cofactor.
-
If cofactor > 1 and cofactor < 10^12: Continue trial division up to sqrt(cofactor).
-
If cofactor > 1 and cofactor >= 10^12: Apply Pollard's rho algorithm.
- Choose f(x) = x^2 + c (mod n) with random c.
- Use Floyd's cycle detection: x = f(x), y = f(f(y)).
- Compute d = gcd(|x - y|, n) at each step.
- If 1 < d < n, d is a non-trivial factor. Recurse on d and n/d.
- If d = n, retry with a different c.
-
Verify: Multiply all found prime factors (with exponents) and confirm the product equals the original n. Test each factor for primality.
-
Present the result in standard form: n = p1^a1 * p2^a2 * ... * pk^ak with p1 < p2 < ... < pk.
Algorithm complexity notes:
| Algorithm | Complexity | Best for |
|---|---|---|
| Trial division | O(sqrt(n)) | n < 10^12 |
| Pollard's rho | O(n^{1/4}) expected | n up to ~10^18 |
| Quadratic sieve | L(n)^{1+o(1)} | n up to ~10^50 |
| GNFS | L(n)^{(64/9)^{1/3}+o(1)} | n > 10^50 |
Got: A complete prime factorization in canonical form, verified by multiplication.
If fail: If Pollard's rho fails to find a factor after many iterations (cycle detected without a non-trivial gcd), try different values of c (at least 5 attempts). If all fail, the cofactor may be prime -- confirm with a primality test.
Step 4: Apply Distribution Analysis (if task = distribution)
Analyze the distribution of primes up to a given bound N.
-
Generate primes using the Sieve of Eratosthenes:
- Create a boolean array of size N + 1, initialized to true.
- Set indices 0 and 1 to false (not prime).
- For each p from 2 to floor(sqrt(N)):
- If p is still marked true, mark all multiples p^2, p^2 + p, p^2 + 2p, ... as false.
- Collect all indices still marked true.
-
Count primes: Compute pi(N) = number of primes up to N.
-
Compare with the Prime Number Theorem:
- PNT approximation: pi(N) ~ N / ln(N).
- Logarithmic integral approximation: Li(N) = integral from 2 to N of 1/ln(t) dt.
- Compute the relative error: |pi(N) - N/ln(N)| / pi(N).
-
Analyze prime gaps (optional):
- Compute gaps between consecutive primes.
- Report the maximum gap, average gap, and any twin primes (gap = 2).
- Average gap near N is approximately ln(N).
-
Present findings in a summary table:
Bound N: 1,000,000
pi(N): 78,498
N/ln(N): 72,382
Li(N): 78,628
Relative error (N/ln(N)): 7.79%
Relative error (Li(N)): 0.17%
Max prime gap: 148 (between 492113 and 492227)
Twin primes: 8,169 pairs
Got: A count of primes with PNT comparison and optional gap analysis.
If fail: If N is too large for in-memory sieving (N > 10^9), use a segmented sieve that processes the range in blocks. If only a count is needed (not a list), use the Meissel-Lehmer algorithm for pi(N) directly.
Step 5: Verify Results Computationally
Cross-check all results using an independent computation method.
-
For primality: If trial division was used, verify with a quick Miller-Rabin pass (or vice versa). For known primes, check against published prime tables or OEIS sequences.
-
For factorization: Multiply all factors and confirm equality with the original input. Independently test each claimed prime factor for primality.
-
For distribution: Spot-check by testing 3-5 individual numbers from the sieve output for primality. Compare pi(N) against published values for standard benchmarks (pi(10^k) for k = 1, ..., 9).
Published values of pi(N):
| N | pi(N) |
|---|---|
| 10 | 4 |
| 100 | 25 |
| 1,000 | 168 |
| 10,000 | 1,229 |
| 100,000 | 9,592 |
| 10^6 | 78,498 |
| 10^7 | 664,579 |
| 10^8 | 5,761,455 |
| 10^9 | 50,847,534 |
- Document the verification with the method used and the outcome.
Got: All results independently verified with no discrepancies.
If fail: If verification reveals a discrepancy, re-run the original computation with extra checks enabled (e.g., verbose trial division logging). The most common errors are off-by-one in sieve bounds, integer overflow in modular arithmetic, and mistaking a pseudoprime for a prime.
Validation
- Task type is correctly classified (primality, factorization, or distribution)
- Algorithm is appropriate for the input size
- Trivial cases (n < 2, n = 2, even n) are handled before general algorithms
- Primality verdicts are definitive (not "probably prime" without qualification)
- Factorizations multiply back to the original number
- Every claimed prime factor has been tested for primality
- Sieve bounds include sqrt(N) coverage for marking composites
- PNT comparison uses the correct formula (N/ln(N) or Li(N))
- Results are verified by an independent method or against published values
- Edge cases (n = 0, 1, 2, negative inputs) are addressed
Pitfalls
-
Forgetting n = 1 is not prime: By convention, 1 is neither prime nor composite. Many algorithms silently misclassify it.
-
Integer overflow in modular exponentiation: When computing a^d mod n for Miller-Rabin, naive exponentiation overflows. Use modular exponentiation (repeated squaring with mod at each step).
-
Sieve off-by-one errors: The sieve must mark composites starting from p^2, not from 2p. Starting from 2p wastes time but is correct; starting from p+1 is wrong.
-
Pollard's rho cycle with d = n: If gcd(|x - y|, n) = n, the algorithm has found the trivial factor. Retry with a different polynomial constant c, not a different starting point.
-
Carmichael numbers fooling Fermat's test: Numbers like 561 = 3 * 11 * 17 pass Fermat's primality test for all coprime bases. Always use Miller-Rabin, not plain Fermat.
-
Confusing pi(n) with the constant pi: The prime counting function pi(n) and the circle constant 3.14159... share notation. Context must be unambiguous.
Related Skills
solve-modular-arithmetic-- Modular arithmetic underpins Miller-Rabin and many factorization methodsexplore-diophantine-equations-- Prime factorization is a prerequisite for solving many Diophantine equationsformulate-quantum-problem-- Shor's algorithm for integer factorization connects primes to quantum computing
GitHub репозиторий
Frequently asked questions
What is the analyze-prime-numbers skill?
analyze-prime-numbers is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform analyze-prime-numbers-related tasks without extra prompting.
How do I install analyze-prime-numbers?
Use the install commands on this page: add analyze-prime-numbers to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does analyze-prime-numbers belong to?
analyze-prime-numbers is in the Testing category, tagged testing.
Is analyze-prime-numbers free to use?
Yes. analyze-prime-numbers is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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