Let X, Tx, A, B, C, x, a and b be given.

Assume Hlin: linear_continuum X Tx.

Assume HAcl: closed_in X Tx A.

Assume HBcl: closed_in X Tx B.

Assume HAB: A ∩ B = Empty.

Assume HCcl: closed_in X Tx C.

Assume HaA: a ∈ A.

Assume HbB: b ∈ B.

Assume HxXC: x ∈ (X ∖ C).

Assume HaComp: a ∈ component_of (X ∖ C) (subspace_topology X Tx (X ∖ C)) x.

Assume HbComp: b ∈ component_of (X ∖ C) (subspace_topology X Tx (X ∖ C)) x.

We prove the intermediate claim Hso: simply_ordered_set X.

An exact proof term for the current goal is (linear_continuum_simply_ordered X Tx Hlin).

We prove the intermediate claim HTxeq: Tx = order_topology X.

An exact proof term for the current goal is (linear_continuum_order_topology_eq X Tx Hlin).

We prove the intermediate claim HTx: topology_on X Tx.

An exact proof term for the current goal is (linear_continuum_topology_on X Tx Hlin).

Set V to be the term component_of (X ∖ C) (subspace_topology X Tx (X ∖ C)) x.

We prove the intermediate claim HVdef: V = component_of (X ∖ C) (subspace_topology X Tx (X ∖ C)) x.

Use reflexivity.

We prove the intermediate claim HaV: a ∈ V.

rewrite the current goal using HVdef (from right to left).

An exact proof term for the current goal is HaComp.

We prove the intermediate claim HbV: b ∈ V.

rewrite the current goal using HVdef (from right to left).

An exact proof term for the current goal is HbComp.

The rest of this subproof is missing.

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