Description of fast matrix multiplication algorithm: ⟨4×4×10:120⟩

Algorithm type

4 X^{3} Y^{4} Z^{3} + 32 X^{2} Y^{2} Z^{2} + 4 X Y^{4} Z + 80 X Y Z

Algorithm definition

The algorithm ⟨4×4×10:120⟩ could be constructed using the following decomposition:

⟨4×4×10:120⟩ = ⟨4×4×1:16⟩ + ⟨4×4×9:104⟩.

This decomposition is defined by the following equality:

Trace (Mul ((\begin{matrix} A_1_1 & A_1_2 & A_1_3 & A_1_4 \\ A_2_1 & A_2_2 & A_2_3 & A_2_4 \\ A_3_1 & A_3_2 & A_3_3 & A_3_4 \\ A_4_1 & A_4_2 & A_4_3 & A_4_4 \end{matrix}), (\begin{matrix} B_1_1 & B_1_2 & B_1_3 & B_1_4 & B_1_5 & B_1_6 & B_1_7 & B_1_8 & B_1_9 & B_1_10 \\ B_2_1 & B_2_2 & B_2_3 & B_2_4 & B_2_5 & B_2_6 & B_2_7 & B_2_8 & B_2_9 & B_2_10 \\ B_3_1 & B_3_2 & B_3_3 & B_3_4 & B_3_5 & B_3_6 & B_3_7 & B_3_8 & B_3_9 & B_3_10 \\ B_4_1 & B_4_2 & B_4_3 & B_4_4 & B_4_5 & B_4_6 & B_4_7 & B_4_8 & B_4_9 & B_4_10 \end{matrix}), (\begin{matrix} C_1_1 & C_1_2 & C_1_3 & C_1_4 \\ C_2_1 & C_2_2 & C_2_3 & C_2_4 \\ C_3_1 & C_3_2 & C_3_3 & C_3_4 \\ C_4_1 & C_4_2 & C_4_3 & C_4_4 \\ C_5_1 & C_5_2 & C_5_3 & C_5_4 \\ C_6_1 & C_6_2 & C_6_3 & C_6_4 \\ C_7_1 & C_7_2 & C_7_3 & C_7_4 \\ C_8_1 & C_8_2 & C_8_3 & C_8_4 \\ C_9_1 & C_9_2 & C_9_3 & C_9_4 \\ C_10_1 & C_10_2 & C_10_3 & C_10_4 \end{matrix}))) = Trace (Mul ((\begin{matrix} A_1_1 & A_1_2 & A_1_3 & A_1_4 \\ A_2_1 & A_2_2 & A_2_3 & A_2_4 \\ A_3_1 & A_3_2 & A_3_3 & A_3_4 \\ A_4_1 & A_4_2 & A_4_3 & A_4_4 \end{matrix}), (\begin{matrix} B_1_1 \\ B_2_1 \\ B_3_1 \\ B_4_1 \end{matrix}), (\begin{matrix} C_1_1 & C_1_2 & C_1_3 & C_1_4 \end{matrix}))) + Trace (Mul ((\begin{matrix} A_1_1 & A_1_2 & A_1_3 & A_1_4 \\ A_2_1 & A_2_2 & A_2_3 & A_2_4 \\ A_3_1 & A_3_2 & A_3_3 & A_3_4 \\ A_4_1 & A_4_2 & A_4_3 & A_4_4 \end{matrix}), (\begin{matrix} B_1_2 & B_1_3 & B_1_4 & B_1_5 & B_1_6 & B_1_7 & B_1_8 & B_1_9 & B_1_10 \\ B_2_2 & B_2_3 & B_2_4 & B_2_5 & B_2_6 & B_2_7 & B_2_8 & B_2_9 & B_2_10 \\ B_3_2 & B_3_3 & B_3_4 & B_3_5 & B_3_6 & B_3_7 & B_3_8 & B_3_9 & B_3_10 \\ B_4_2 & B_4_3 & B_4_4 & B_4_5 & B_4_6 & B_4_7 & B_4_8 & B_4_9 & B_4_10 \end{matrix}), (\begin{matrix} C_2_1 & C_2_2 & C_2_3 & C_2_4 \\ C_3_1 & C_3_2 & C_3_3 & C_3_4 \\ C_4_1 & C_4_2 & C_4_3 & C_4_4 \\ C_5_1 & C_5_2 & C_5_3 & C_5_4 \\ C_6_1 & C_6_2 & C_6_3 & C_6_4 \\ C_7_1 & C_7_2 & C_7_3 & C_7_4 \\ C_8_1 & C_8_2 & C_8_3 & C_8_4 \\ C_9_1 & C_9_2 & C_9_3 & C_9_4 \\ C_10_1 & C_10_2 & C_10_3 & C_10_4 \end{matrix})))

N.B.: for any matrices A, B and C such that the expression Tr(Mul(A,B,C)) is defined, one can construct several trilinear homogeneous polynomials P(A,B,C) such that P(A,B,C)=Tr(Mul(A,B,C)) (P(A,B,C) variables are A,B and C's coefficients). Each trilinear P expression encodes a matrix multiplication algorithm: the coefficient in C_i_j of P(A,B,C) is the (i,j)-th entry of the matrix product Mul(A,B)=Transpose(C).

Algorithm description

These encodings are given in compressed text format using the maple computer algebra system. In each cases, the last line could be understood as a description of the encoding with respect to classical matrix multiplication algorithm. As these outputs are structured, one can construct easily a parser to its favorite format using the maple documentation without this software.

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