We prove the intermediate claim Li6: OSNo i6.
An exact proof term for the current goal is OSNo_Octonion_i6.
We prove the intermediate claim Li0: OSNo i0.
An exact proof term for the current goal is OSNo_Octonion_i0.
We prove the intermediate claim Li2: OSNo i2.
An exact proof term for the current goal is OSNo_Quaternion_j.
We prove the intermediate claim Li0i6: OSNo (i0 i6).
An exact proof term for the current goal is OSNo_mul_OSNo i0 i6 ?? ??.
Apply OSNo_proj0proj1_split (i0 i6) (:-: i2) ?? (OSNo_minus_OSNo i2 ??) to the current goal.
rewrite the current goal using minus_OSNo_proj0 i2 ?? (from left to right).
rewrite the current goal using OSNo_p0_j (from left to right).
rewrite the current goal using mul_OSNo_proj0 i0 i6 ?? ?? (from left to right).
rewrite the current goal using OSNo_p0_i6 (from left to right).
rewrite the current goal using OSNo_p1_i6 (from left to right).
rewrite the current goal using OSNo_p0_i0 (from left to right).
rewrite the current goal using OSNo_p1_i0 (from left to right).
We will prove 0 * 0 + - ((- j) ' * 1) = - j.
rewrite the current goal using mul_HSNo_0L 0 HSNo_0 (from left to right).
rewrite the current goal using conj_minus_HSNo j HSNo_Quaternion_j (from left to right).
rewrite the current goal using conj_HSNo_j (from left to right).
rewrite the current goal using minus_HSNo_invol j HSNo_Quaternion_j (from left to right).
We will prove 0 + - (j * 1) = - j.
rewrite the current goal using mul_HSNo_1R j HSNo_Quaternion_j (from left to right).
An exact proof term for the current goal is add_HSNo_0L (- j) (HSNo_minus_HSNo j HSNo_Quaternion_j).
rewrite the current goal using minus_OSNo_proj1 i2 ?? (from left to right).
rewrite the current goal using OSNo_p1_j (from left to right).
rewrite the current goal using mul_OSNo_proj1 i0 i6 ?? ?? (from left to right).
rewrite the current goal using OSNo_p0_i6 (from left to right).
rewrite the current goal using OSNo_p1_i6 (from left to right).
rewrite the current goal using OSNo_p0_i0 (from left to right).
rewrite the current goal using OSNo_p1_i0 (from left to right).
We will prove (- j) * 0 + 1 * 0 ' = - 0.
rewrite the current goal using conj_HSNo_id_SNo 0 SNo_0 (from left to right).
rewrite the current goal using mul_HSNo_0R 1 HSNo_1 (from left to right).
rewrite the current goal using minus_HSNo_0 (from left to right).
rewrite the current goal using mul_HSNo_0R (- j) (HSNo_minus_HSNo j HSNo_Quaternion_j) (from left to right).
An exact proof term for the current goal is add_HSNo_0L 0 HSNo_0.