algebraic-arrays 1.3.4

Abstract algebric structures for GPU-efficient computation

Algebraic: Multi-Backend Semiring Algebra

A Python package providing semiring algebra implementations with support for NumPy, JAX, and PyTorch backends.

Overview

This package provides abstract semiring interfaces and concrete implementations for:

• Tropical semirings (MinPlus, MaxPlus) with smooth variants for differentiability
• Max-Min algebras for robustness semantics
• Boolean algebras with De Morgan and Heyting algebra variants
• Counting semirings
• Custom semirings via the extensible interface

Features

• AlgebraicArray : Arrays with semiring semantics: override + , * , @ to use custom algebras
• Multi-Backend : Supports NumPy, JAX, and PyTorch backends with a unified API
• Differentiable Kernels : Smooth approximations of boolean and tropical operations for neural networks
• Rich Semiring Library : Tropical, Boolean, Max-Min, Counting, and custom semirings
• Polynomial Algebras : Sparse and dense multilinear polynomials over semirings

Quick Start

Recommended Import

import algebraic

The top-level algebraic module re-exports all array operations, semiring specifications, and polynomial types.

Basic Semiring Operations

from algebraic.semirings import tropical_semiring, max_min_algebra, boolean_algebra

# Tropical semiring (MaxPlus: max is addition, + is multiplication)
maxplus = tropical_semiring(minplus=False)
a = maxplus.add(2.0, 3.0)  # max(2, 3) = 3
b = maxplus.mul(2.0, 3.0)  # 2 + 3 = 5

# Tropical semiring (MinPlus: min is addition, + is multiplication)
minplus = tropical_semiring(minplus=True)  # or just tropical_semiring()
c = minplus.add(2.0, 3.0)  # min(2, 3) = 2
d = minplus.mul(2.0, 3.0)  # 2 + 3 = 5

# Max-Min algebra (for robustness/STL semantics)
maxmin = max_min_algebra()
e = maxmin.add(-0.5, 0.2)  # max(-0.5, 0.2) = 0.2
f = maxmin.mul(-0.5, 0.2)  # min(-0.5, 0.2) = -0.5

# Boolean algebra
bool_alg = boolean_algebra(mode="logic")
true = bool_alg.one
false = bool_alg.zero
result = bool_alg.add(true, false)  # True OR False = True

AlgebraicArray: Arrays with Semiring Semantics

The AlgebraicArray class wraps backend arrays and overrides arithmetic operations to use semiring semantics.

import algebraic
from algebraic.semirings import tropical_semiring

# Create algebraic arrays with tropical semiring
tropical = tropical_semiring(minplus=True)
a = algebraic.array([1.0, 2.0, 3.0], semiring=tropical, backend="numpy")
b = algebraic.array([4.0, 5.0, 6.0], semiring=tropical, backend="numpy")

# Element-wise operations use semiring semantics
c = a + b  # Tropical addition: [min(1,4), min(2,5), min(3,6)] = [1, 2, 3]
d = a * b  # Tropical multiplication: [1+4, 2+5, 3+6] = [5, 7, 9]

# Reductions use semiring operations
total = algebraic.sum(a)  # min(1, 2, 3) = 1
product = algebraic.prod(a)  # 1 + 2 + 3 = 6

# Matrix multiplication with @ operator
A = algebraic.array([[1.0, 2.0], [3.0, 4.0]], semiring=tropical, backend="numpy")
B = algebraic.array([[5.0, 6.0], [7.0, 8.0]], semiring=tropical, backend="numpy")
C = A @ B  # Tropical matmul: C[i,j] = min_k(A[i,k] + B[k,j])
# Result: [[6, 7], [8, 9]]

Boolean Algebra for Graph and Logic Operations

import algebraic
from algebraic.semirings import boolean_algebra

# Boolean algebra for reachability
bool_alg = boolean_algebra(mode="logic")

# Adjacency matrix: edge from i to j
adj = algebraic.array([
    [False, True,  False],
    [False, False, True],
    [True,  False, False]
], semiring=bool_alg, backend="numpy")

# Matrix multiplication computes 2-step reachability
reach_2 = adj @ adj
# reach_2[i,j] = True if there's a path of length 2 from i to j

# Transitive closure: adj + adj^2 + adj^3 + ...
reach = adj
for _ in range(3):
    reach = reach + (reach @ adj)
# reach[i,j] = True if there's any path from i to j

Smooth Boolean Operations for Learning

import algebraic
from algebraic.semirings import boolean_algebra

# Differentiable boolean operations for neural networks
smooth_bool = boolean_algebra(mode="smooth", temperature=10.0)
soft_bool = boolean_algebra(mode="soft")

# Example: Soft logical operations on continuous values
x = algebraic.array([0.9, 0.8, 0.1], semiring=soft_bool, backend="numpy")
y = algebraic.array([0.7, 0.3, 0.2], semiring=soft_bool, backend="numpy")

# Soft AND: element-wise multiplication
z_and = x * y  # [0.63, 0.24, 0.02]

# Soft OR: probabilistic OR formula
z_or = x + y  # [0.97, 0.86, 0.28]

JAX-Specific Transformations

AlgebraicArray is registered as a JAX PyTree (via algebraic.utils.jax), so standard JAX transforms work out of the box:

import jax
import algebraic
import algebraic.utils.jax  # registers AlgebraicArray as a JAX PyTree
from algebraic.semirings import tropical_semiring

tropical = tropical_semiring(minplus=True)

@jax.jit
def shortest_paths(dist_matrix):
    """Compute all-pairs shortest paths using tropical matrix multiplication."""
    n = dist_matrix.shape[0]
    result = dist_matrix
    for _ in range(n - 1):
        result = result @ dist_matrix
    return result

For batching, use algebraic.vmap which delegates to jax.vmap or torch.vmap depending on the backend:

from algebraic import vmap

batched_fn = vmap(my_fn, backend="jax")

Advanced Features

Functional Index Updates

AlgebraicArray supports functional index updates with semiring operations:

import algebraic
from algebraic.semirings import tropical_semiring

tropical = tropical_semiring(minplus=True)
arr = algebraic.array([1.0, 2.0, 3.0, 4.0], semiring=tropical, backend="numpy")

# Functional updates (returns new array)
new_arr = arr.at[1].set(0.5)  # Set index 1 to 0.5

# Add using semiring addition (min for tropical)
updated = arr.at[1].add(1.5)  # arr[1] = min(2.0, 1.5) = 1.5

# Multiply using semiring multiplication (+ for tropical)
scaled = arr.at[2].multiply(2.0)  # arr[2] = 3.0 + 2.0 = 5.0

Multilinear Polynomials

Work with sparse and dense polynomial representations over semirings:

from algebraic.polynomials import PolyDict, MonomialBasis
from algebraic.semirings import boolean_algebra

bool_alg = boolean_algebra(mode="logic")

# Sparse representation (efficient for few terms)
x0 = PolyDict.variable(0, num_vars=3, algebra=bool_alg, backend="numpy")
x1 = PolyDict.variable(1, num_vars=3, algebra=bool_alg, backend="numpy")
p = x0 * x1 + x1  # Polynomial: (x0 AND x1) OR x1

# Evaluate at a point
result = p.evaluate({0: True, 1: False, 2: True})

# Dense monomial basis (efficient for many terms)
mb0 = MonomialBasis.variable(0, num_vars=2, bool_alg, backend="numpy")
mb1 = MonomialBasis.variable(1, num_vars=2, bool_alg, backend="numpy")
q = mb0 * mb1  # Represented as dense tensor

Core Concepts

Semirings

A semiring :math: (S, \oplus, \otimes, \mathbf{0}, \mathbf{1}) consists of:

• Addition (:math: \oplus ): Combines alternative paths/outcomes
• Multiplication (:math: \otimes ): Combines sequential compositions
• Additive identity (:math: \mathbf{0} ): Identity for :math: \oplus
• Multiplicative identity (:math: \mathbf{1} ): Identity for :math: \otimes

Lattices

Bounded distributive lattices specialize semirings where:

• Join (:math: \lor ) = Addition (:math: \oplus )
• Meet (:math: \land ) = Multiplication (:math: \otimes )
• Top = Multiplicative identity (:math: \mathbf{1} )
• Bottom = Additive identity (:math: \mathbf{0} )

Available Semirings

Name	Addition	Multiplication	Use Case
Boolean	Logical OR	Logical AND	Logic, SAT
Tropical (MaxPlus)	max	+	Optimization, path problems
Tropical (MinPlus)	min	+	Shortest paths, distances
Max-Min	max	min	Robustness degrees, STL
Counting	+	$\times$	Counting paths

Use Cases

Graph Algorithms

• Shortest paths : Use tropical semirings for Floyd-Warshall algorithm
• Reachability : Boolean algebra for transitive closure
• Path counting : Counting semiring for enumeration

Formal Verification

• Temporal logic : Signal Temporal Logic (STL) with max-min algebra
• Automata theory : Weighted automata with tropical semirings
• Model checking : Boolean polynomials for state space exploration

Machine Learning

• Differentiable logic : Soft/smooth boolean operations for neural networks
• Attention mechanisms : Tropical attention for robust aggregation
• Graph neural networks : Semiring-based message passing

Optimization

• Dynamic programming : Tropical semirings for Bellman equations
• Constraint satisfaction : Boolean algebra for SAT solving
• Resource allocation : Max-min algebra for bottleneck optimization