2026-06-22 08:21:44
The n queens problem is to place on an n × n chessboard n queens so that none attacks any other. This means there is only one queen on every horizontal, vertical, and diagonal line.
When n is a prime number ≥ 5, it is sufficient to place the queens on a line that has slope 2, 3, 4, …, n − 2. (The slope cannot be 1 because that’s a diagonal. And it cannot be n − 1 because n − 1 = −1 mod n is also a diagonal.) [1]
Here we imagine the top and bottom edge being identified. Geometrically, this makes the chessboard a cylinder. Algebraically, the points on a line of slope s have the coordinates
(a + k, b + ks)
where addition is carried out mod n.
All solutions to the n queens problem have this form when n = 5. Some solutions will have this form for larger prime values of n but not all.
For example, when n = 7, here is a solution where all the queens are on a line of slope 2.
But here is another solution where the queens do not all lie on a line of constant slope.
[1] W. H. Bussey. A Note on the Problem of the Eight Queens. The American Mathematical Monthly, Vol. 29, No. 7 (August 1922), pp. 252–253
The post Queens on a prime order board first appeared on John D. Cook.2026-06-21 05:41:16
I’ve written a couple posts lately on getting an LLM to generate code to solve chess problems. The first used Claude to generate Prolog and the second used ChatGPT to generate Prolog. This post will use Claude to generate Z3/Python code.
The puzzle is one I’ve written about before:
Place all the pieces—king, queen, two bishops, two knights, and two rooks—on a 6 × 5 chessboard, with the requirement that the two bishops be on opposite colored squares and no piece is attacking another.
Incidentally, it’s common for “piece” to exclude pawns, as above. But then what do you call all the things on a chessboard? You might call them “chess pieces,” in which case a pawn is a “chess piece” but not a “piece.” One convention is to use “chessmen” or simply “men” to include pieces and pawns.
This was the prompt I used.
Write Z3/Python code to find all solutions to the following chess puzzle.
Place all the pieces—king, queen, two bishops, two knights, and two rooks—on a 6 × 5 chessboard, with the requirement that the two bishops be on opposite colored squares and no piece is attacking another.
The code found 192 = 8 × 24 solutions. The factor of 8 comes from 23 ways of swapping the pairs of bishops, knights, and rooks. The script reports
Total raw solutions: 192 Unique solutions (deduplicating piece-pair swaps): 24 ── Solution 1 ── 0 1 2 3 4 0 . K . . N 1 . . . . B 2 . . R . . 3 Q . . . . 4 . . . R . 5 . B . . N King: (0,1) Queen: (3,0) Bishop1: (5,1) [light] Bishop2: (1,4) [dark] Knight1: (5,4) Knight2: (0,4) Rook1: (4,3) Rook2: (2,2) ── Solution 2 ── 0 1 2 3 4 0 N . . K . 1 B . . . . 2 . . R . . 3 . . . . Q 4 . R . . . 5 N . . B . King: (0,3) Queen: (3,4) Bishop1: (5,3) [light] Bishop2: (1,0) [dark] Knight1: (5,0) Knight2: (0,0) Rook1: (4,1) Rook2: (2,2) ... ── Solution 24 ── 0 1 2 3 4 0 B . . B . 1 N . . . . 2 . . . . Q 3 . . R . . 4 . R . . . 5 N . . K . King: (5,3) Queen: (2,4) Bishop1: (0,0) [light] Bishop2: (0,3) [dark] Knight1: (5,0) Knight2: (1,0) Rook1: (3,2) Rook2: (4,1)
Here’s the code.
"""
Chess Puzzle Solver using Z3
Place king, queen, 2 bishops, 2 knights, 2 rooks on a 6×5 board
such that:
- The two bishops are on opposite-colored squares
- No piece attacks any other piece
"""
from z3 import (
Int, Solver, Or, And, Not, Distinct, If,
sat, ForAll, Implies
)
import itertools
ROWS = 6
COLS = 5
TOTAL_CELLS = ROWS * COLS # 30
PIECES = ["king", "queen", "bishop1", "bishop2", "knight1", "knight2", "rook1", "rook2"]
N = len(PIECES) # 8 pieces
def cell(r, c):
return r * COLS + c
def pos_to_rc(pos):
return pos // COLS, pos % COLS
def color(r, c):
"""Square color: 0=light, 1=dark"""
return (r + c) % 2
def attacks_king(r1, c1, r2, c2):
return max(abs(r1 - r2), abs(c1 - c2)) == 1
def attacks_queen(r1, c1, r2, c2):
return (r1 == r2 or c1 == c2 or
abs(r1 - r2) == abs(c1 - c2))
def attacks_bishop(r1, c1, r2, c2):
return abs(r1 - r2) == abs(c1 - c2)
def attacks_rook(r1, c1, r2, c2):
return r1 == r2 or c1 == c2
def attacks_knight(r1, c1, r2, c2):
dr, dc = abs(r1 - r2), abs(c1 - c2)
return (dr == 1 and dc == 2) or (dr == 2 and dc == 1)
# Map piece index to its attack function
ATTACK_FN = {
0: attacks_king,
1: attacks_queen,
2: attacks_bishop,
3: attacks_bishop,
4: attacks_knight,
5: attacks_knight,
6: attacks_rook,
7: attacks_rook,
}
def solve_all():
solutions = []
# Each piece gets an integer position in [0, TOTAL_CELLS)
pos = [Int(f"pos_{p}") for p in PIECES]
s = Solver()
# All positions in valid range
for p in pos:
s.add(p >= 0, p
Related post: Lessons Learned With the Z3 SAT/SMT Solver
The post All pieces on a 6 by 5 board first appeared on John D. Cook.
2026-06-17 22:23:51
I’ve been testing Claude’s ability to generate Lean 4 code to prove theorems. I’ve written about a couple experiments that verified calculations. I did not write about my failed attempt to get Claude to formalize a proof of the pqr theorem for seminorms.
This time I asked Claude to formally prove the theorem from the previous post on partial fraction decomposition in an abstract setting. Unlike the previous experiments, I did not give it a proof or calculation to verify; I asked it to generate a proof.
This was the prompt:
Write a proof in Lean 4 for the following generalization of partial fraction decomposition.
If a ring R is a principle ideal domain (PID), then every element c of the field of fractions over R can be written in the form \[c = \sum_i \frac{a_i}{p_i^{r_i}}\]
where the p_i are nonassociate irreducible elements of R, the r_i are non-negative integers, and the elements a_i and p_i are relatively prime.
This was Claude’s immediate response:
I’ll work through this carefully, as it’s a substantial formalization task. Let me think through what’s available in Mathlib and what needs to be constructed.
This is a genuinely hard Lean 4 formalization problem. Let me think carefully about what’s in Mathlib, what the statement precisely means, and what proof strategy is realistic.
It also stated its overall proof strategy:
Proof strategy: Write
c = a/bin lowest terms. Factorb = ∏ pᵢ^rᵢ. Use the Chinese Remainder Theorem / Bezout identity to decomposea/binto partial fractions.
If I needed to prove the theorem by hand, this suggestion alone could be very helpful.
The first attempt generated code that would not build. As before, a lot of the problems seem to stem from things moving around in Mathlib due to refactorings. There are also occasional hallucinations.
I did not offer any help other than pasting in error messages after each failure. When working on a real problem, I’d be more interactive. But as a test, I just passively pasted error messages and tried again. It took 11 iterations, but I finally got a proof. The proof had five sections marked “sorry,” which is essentially a TODO note indicating an unproven assumption.
I asked if it could explain or remove the sorries, and it said it could remove three of them. But the generated code did not build and I hit a session limit before I could debug the code. Here is the code with five sorry sections.
/-
PartialFractions.lean (v11 — final)
-/
import Mathlib
open UniqueFactorizationMonoid
variable {R : Type*} [CommRing R] [IsDomain R] [IsPrincipalIdealRing R]
structure PFDSummand (R : Type*) [CommRing R] where
prime : R
exponent : ℕ
numer : R
noncomputable def PFDSummand.val [CommRing R] [IsDomain R] (s : PFDSummand R) :
FractionRing R :=
algebraMap R (FractionRing R) s.numer /
algebraMap R (FractionRing R) (s.prime ^ s.exponent)
structure IsPFD [CommRing R] [IsDomain R] [IsPrincipalIdealRing R]
(terms : List (PFDSummand R)) (c : FractionRing R) : Prop where
irred : ∀ s ∈ terms, Irreducible s.prime
nonAssoc : ∀ s ∈ terms, ∀ t ∈ terms, s ≠ t → ¬Associated s.prime t.prime
coprime : ∀ s ∈ terms, IsCoprime s.numer s.prime
sum_eq : (terms.map PFDSummand.val).sum = c
private lemma algMap_ne_zero {a : R} (h : a ≠ 0) :
(algebraMap R (FractionRing R)) a ≠ 0 :=
map_ne_zero_iff _ (IsFractionRing.injective R (FractionRing R)) |>.mpr h
private lemma exists_num_denom (c : FractionRing R) :
∃ a b : R, b ≠ 0 ∧
(algebraMap R (FractionRing R)) a / (algebraMap R (FractionRing R)) b = c := by
obtain ⟨a, b, hb, hab⟩ := IsFractionRing.div_surjective (A := R) c
exact ⟨a, b, nonZeroDivisors.ne_zero hb, hab⟩
-- ======================================================================
-- §6 Bézout splitting
-- ======================================================================
private lemma bezout_split (x y : R) (hcop : IsCoprime x y)
(hx : x ≠ 0) (hy : y ≠ 0) (e : R) :
∃ s t : R, s * x + t * y = 1 ∧
(algebraMap R (FractionRing R) e) /
((algebraMap R (FractionRing R) x) * (algebraMap R (FractionRing R) y)) =
(algebraMap R (FractionRing R) (e * t)) / (algebraMap R (FractionRing R) x) +
(algebraMap R (FractionRing R) (e * s)) / (algebraMap R (FractionRing R) y) := by
obtain ⟨s, t, hst⟩ := hcop
refine ⟨s, t, hst, ?_⟩
have hxF : (algebraMap R (FractionRing R)) x ≠ 0 := algMap_ne_zero hx
have hyF : (algebraMap R (FractionRing R)) y ≠ 0 := algMap_ne_zero hy
have hxyF : (algebraMap R (FractionRing R)) x *
(algebraMap R (FractionRing R)) y ≠ 0 := mul_ne_zero hxF hyF
have hst_F : (algebraMap R (FractionRing R)) s * (algebraMap R (FractionRing R)) x +
(algebraMap R (FractionRing R)) t * (algebraMap R (FractionRing R)) y = 1 := by
have h := congr_arg (algebraMap R (FractionRing R)) hst
simp only [map_add, map_mul, map_one] at h; exact h
-- Prove: ι e / (ι x * ι y) = ι(e*t)/ι x + ι(e*s)/ι y
-- Strategy: show RHS = LHS via eq_div_iff, simplify, linear_combination.
symm
rw [eq_div_iff hxyF, add_mul, div_mul_eq_mul_div, div_mul_eq_mul_div]
-- Goal: ι(e*t)*(ι x*ι y)/ι x + ι(e*s)*(ι x*ι y)/ι y = ι e
-- The mul_comm on the product inside:
rw [show (algebraMap R (FractionRing R)) x * (algebraMap R (FractionRing R)) y =
(algebraMap R (FractionRing R)) y * (algebraMap R (FractionRing R)) x from mul_comm _ _]
-- Now: ι(e*t)*(ι y*ι x)/ι x + ι(e*s)*(ι y*ι x)/ι y = ι e
-- Use field_simp to clear remaining denominators
field_simp [hxF, hyF]
-- Now a polynomial goal: close with linear_combination
simp only [map_mul]
linear_combination (algebraMap R (FractionRing R) e) * hst_F
-- ======================================================================
-- §7 Coprime numerator reduction
-- ======================================================================
private lemma coprime_numer_exists {p : R} (hp : Irreducible p) (a : R) (n : ℕ) :
∃ a' q : R, a = a' + q * p ^ n ∧ IsCoprime a' p := by
rcases Classical.em (p ∣ a) with _h | h
· exact ⟨0, 0, by sorry, by sorry⟩
· exact ⟨a, 0, by ring,
isCoprime_comm.mpr ((irreducible_iff_prime.mp hp).coprime_iff_not_dvd.mpr h)⟩
-- ======================================================================
-- §8 Main theorem
-- ======================================================================
private def emptyPFD (c : FractionRing R) (hc : c = 0) :
∃ terms : List (PFDSummand R), IsPFD terms c :=
⟨[], { irred := by simp, nonAssoc := by simp, coprime := by simp,
sum_eq := by simp [hc] }⟩
private lemma isPFD_of_denom : ∀ (d : R) (e : R),
∃ terms : List (PFDSummand R),
IsPFD terms ((algebraMap R (FractionRing R) e) /
(algebraMap R (FractionRing R) d)) := by
intro d
induction d using UniqueFactorizationMonoid.induction_on_coprime with
| h0 =>
intro e; simp only [map_zero, div_zero]
exact emptyPFD 0 rfl
| h1 =>
intro e
-- Unit denominator: sorry for now (§9C)
exact ⟨[], { irred := by simp, nonAssoc := by simp,
coprime := by simp, sum_eq := by simp; sorry }⟩
| hpr =>
rename_i prime_elem exp hp_prime
intro e
have hp_irred : Irreducible prime_elem := irreducible_iff_prime.mpr hp_prime
obtain ⟨e', _q, _he, he'_cop⟩ := coprime_numer_exists hp_irred e exp
exact ⟨[⟨prime_elem, exp, e'⟩], {
irred := fun s hs => by
simp only [List.mem_singleton] at hs; subst hs; exact hp_irred
nonAssoc := fun s hs t ht hne => by
simp only [List.mem_singleton] at hs ht; subst hs; subst ht; exact absurd rfl hne
coprime := fun s hs => by
simp only [List.mem_singleton] at hs; subst hs; exact he'_cop
sum_eq := by
simp only [List.map_singleton, List.sum_singleton, PFDSummand.val]; sorry }⟩
| hcp =>
rename_i x y hrel ih_x ih_y
intro e
-- Handle the case where x = 0 or y = 0 directly
rcases eq_or_ne x 0 with rfl | hx
· -- x = 0: denominator = 0*y = 0, so quotient = 0
simp only [zero_mul, map_zero, div_zero]
exact emptyPFD 0 rfl
rcases eq_or_ne y 0 with rfl | hy
· -- y = 0: denominator = x*0 = 0, so quotient = 0
simp only [mul_zero, map_zero, div_zero]
exact emptyPFD 0 rfl
-- Both nonzero: apply Bézout splitting
-- IsCoprime x y from IsRelPrime x y (using IsRelPrime.isCoprime)
have hcop : IsCoprime x y := hrel.isCoprime
obtain ⟨s, t, _hst, hsplit⟩ := bezout_split x y hcop hx hy e
obtain ⟨terms_x, hpfd_x⟩ := ih_x (e * t)
obtain ⟨terms_y, hpfd_y⟩ := ih_y (e * s)
exact ⟨terms_x ++ terms_y, {
irred := fun s' hs' => by
rw [List.mem_append] at hs'
exact hs'.elim (hpfd_x.irred s') (hpfd_y.irred s')
nonAssoc := fun s' hs' t' ht' hne => by
rw [List.mem_append] at hs' ht'
rcases hs' with hs' | hs' rcases ht' with ht' | ht'
· exact hpfd_x.nonAssoc s' hs' t' ht' hne
· intro; sorry
· intro; sorry
· exact hpfd_y.nonAssoc s' hs' t' ht' hne
coprime := fun s' hs' => by
rw [List.mem_append] at hs'
exact hs'.elim (hpfd_x.coprime s') (hpfd_y.coprime s')
sum_eq := by
rw [List.map_append, List.sum_append, hpfd_x.sum_eq, hpfd_y.sum_eq]
-- Goal: ι(e*t)/ι x + ι(e*s)/ι y = ι e / ι(x*y)
-- hsplit: ι e/(ι x*ι y) = ι(e*t)/ι x + ι(e*s)/ι y
-- So: ι(e*t)/ι x + ι(e*s)/ι y = ι e/(ι x*ι y) = ι e/ι(x*y)
rw [← hsplit, map_mul] }⟩
theorem pid_partial_fraction_decomposition (c : FractionRing R) :
∃ terms : List (PFDSummand R), IsPFD terms c := by
obtain ⟨a, b, _hb, hc⟩ := exists_num_denom c
rw [← hc]; exact isPFD_of_denom b a
section IntExample
example (c : FractionRing ℤ) :
∃ terms : List (PFDSummand ℤ), IsPFD terms c :=
pid_partial_fraction_decomposition c
end IntExample
The post Formalizing a ring theorem with Lean 4 and Claude first appeared on John D. Cook.
2026-06-17 01:56:27
Nearly everyone who has seen partial fraction decomposition was introduced to it as a way to compute integrals. If P(x) and Q(x) are polynomials, then you can break their ratio P(x)/Q(x) into a sum of terms that can each be integrated in closed form. As with most topics in a calculus class, partial fractions go by in a blur.
This post will look at partial fractions more generally.
Every polynomial with real coefficients can be factored into a product of linear and irreducible quadratic terms. But actually calculating this factorization is difficult if the degree of the denominator is large.
The quadratic equation is easy to use. There are analogs for 3rd and 4th order polynomials, but they’re cumbersome. And there is no formula in general for finding roots of polynomials of degree 5 or higher.
You could find the roots numerically, but if you’re going to go that route, maybe you should evaluate your integral numerically.
Still, it is useful in proving theorems to know that a partial fraction decomposition exists, even if in practice you cannot calculate it.
Rational polynomials over the real numbers can be factored into powers of linear terms and irreducible quadratic terms. There are no irreducible quadratics over the complex numbers thanks to the Fundamental Theorem of Algebra, and every polynomial can be factored into a product of linear terms.
This means every rational in z can be broken into a sum of a polynomial in z and polynomials in 1/(z − zi) where the zi are the roots of the denominator. This fact is important, for example, in contour integration.
The concept of partial fraction decomposition can be generalized to the field of fractions over a ring R [1].
If the ring R is a principle ideal domain (PID) [2], then every element c of the field K of fractions over R can be written in the form
where the pi are nonassociate [3] irreducible elements of R, the ri are non-negative integers, and the elements ai and pi are relatively prime.
When R is the ring of of polynomials over a field, R is a PID, and the field of fractions is the set of rational functions over that field. When the field is the real or complex numbers, we get the results above. But the field could be something else, such as a finite field.
When R is the ring of integers, the irreducible elements are prime numbers. The nonassociate condition means you can’t count p and −p as distinct elements, so practically this means we only look at positive primes. The field of fractions is the rational numbers. So the theorem above says that every rational number can be written as a sum of fractions where the denominators of the fractions are prime powers and the numerators are relatively prime to the denominators.
The way you would decompose a rational number into fractions with prime power denominators is analogous to the way you’d do partial fraction decomposition in a calculus class. For example, suppose we want to decompose 46/75. The distinct prime factors of 75 are 3 and 5, and so we’d look for fractions with denominators 3, 5, and 25, and in fact
[1] The field of fractions over R is the set of formal terms a/b where a and b are in R and b ≠ 0. Operations are defined by analogy with rational numbers. If R is an integral domain, the field of fractions really is a field.
[2] A ring is a PID if every ideal can be generated by a single element.
[3] Two elements of an integral domain are said to be associate if they generate the same ideal.
The post Partial fraction decomposition first appeared on John D. Cook.2026-06-16 19:14:01
You can’t prove a theorem by just checking a few examples. Except sometimes you can.
A few weeks ago I wrote Pentagonal numbers are truncated triangular numbers. In a nutshell, if the pentagonal numbers are defined by
Pn = (3n² − n)/2
and the triangular numbers by
Tn = (n² + n)/2
then
Pn = T2n − 1 − Tn − 1.
Here’s a visualization of the equation.
Note that the equation asserts that two quadratic polynomials are equal. If the two polynomials are equal at three points, then they’re equal everywhere. We might as well make life easy and choose n = 0, 1, and 2.
If you’d like, you could do this in code.
>>> P = lambda n: (3*n**2 - n)/2 >>> T = lambda n: (n**2 + n)/2 >>> for n in [0, 1, 2]: assert(P(n) == T(2*n-1) - T(n-1))
This provides a rigorous proof, not just a sanity check.
Sometimes checking a few points is not enough to prove an equation with certainty, but it is enough to establish an equation with high probability. More on that here.
2026-06-16 07:57:54
The nth pentagonal number Pn is the number of dots in diagrams like those below with n concentric pentagons.
We have the formula
Pn = (3n² − n)/2
where n is a positive integer. If n is an integer but not positive, the equation above defines a generalized pentagonal number.
If you’re given an n, you can easily compute Pn. But suppose you’re given a large number x. How would you determine if it is a pentagonal number? And if it is a pentagonal number, how would you find n such that x = Pn?
If
x = Pn = (3n² − n)/2
then we can solve a quadratic equation for n:
n = (1 ± √(24x + 1))/6.
If 24x + 1 is not a perfect square, n is not an integer and x is not a pentagonal number, ordinary or generalized.
For example,
√(24 × 20260615 + 1)) = 22051.185…
and so 20260615 is not a pentagonal number nor a generalized pentagonal number.
Now suppose
x = 170141183460469231731687303715884105727.
Is this a pentagonal number? You can’t just compute √(24x + 1) in floating point arithmetic because the result is a 20-digit number, and floating point number have 15 digits of precision, so you can’t tell whether the result is an integer.
However, you can compute
⌊√(24x + 1)⌋
with only integer arithmetic using the sqrt_floor function from this post.
def sqrt_floor(n):
a = n
b = (n + 1) // 2
while b < a:
a = b
b = (a*a + n) // (2*a)
return a
The following prints a positive number,
x = 2**127 - 1 y = 24*x + 1 r = sqrt_floor(y) print(y - r**2)
which tells us y is not a perfect square.
Now suppose y is a perfect square. Then the roots of
(1 ± √(24x + 1))/6
are rational, but are they integers? In fact one, and only one, of the roots will be an integer. If
24x + 1 = r²
then r is congruent to ±1 mod 6 because the left side is congruent to 1 mod 6. If r = 1 mod 6 then the smaller root is an integer, and if r = 5 mod 6 then the larger root is an integer.
So if 24x + 1 = r², then x is a pentagonal number if r = 5 mod 6 and a generalized pentagonal number otherwise.
The function pentagonal_index takes a number x and return n if x = Pn and None if no such n exists.
def pentagonal_index(x):
y = 24*x + 1
r = sqrt_floor(y)
if r*r != y:
return None
if r % 6 == 5:
return (1 + r) // 6
else:
return (1 - r) // 6
We can test this with the following code.
P = lambda n: (3*n**2 - n) // 2
for n in [2, 3, -4, -5, 10**200]:
assert(pentagonal_index(P(n)) == n)
Note that P(10**200) is too big to fit into a float, but the code works fine. This is because we use integer division (//) everywhere. If we had said
P = lambda n: (3*n**2 - n) / 2
the test above would pass for the small values of n but output
OverflowError: integer division result too large for a float
when it came to n = 10200.
