reserve A, B for non empty set,
  A1, A2, A3 for non empty Subset of A;
reserve X for TopSpace;
reserve X for non empty TopSpace;
reserve X1, X2 for non empty SubSpace of X;
reserve X0, X1, X2, Y1, Y2 for non empty SubSpace of X;
reserve X, Y for non empty TopSpace;
reserve f for Function of X,Y;
reserve X,Y,Z for non empty TopSpace;
reserve f for Function of X,Y,
  g for Function of Y,Z;
reserve X, Y for non empty TopSpace,
  X0 for non empty SubSpace of X;
reserve f for Function of X,Y;
reserve f for Function of X,Y,
  X0 for non empty SubSpace of X;
reserve X, Y for non empty TopSpace,
  X0, X1 for non empty SubSpace of X;
reserve f for Function of X,Y,
  g for Function of X0,Y;
reserve X0, X1, X2 for non empty SubSpace of X;
reserve f for Function of X,Y,
  g for Function of X0,Y;

theorem Th75:
  X1 is SubSpace of X0 implies for x0 being Point of X0, x1 being
  Point of X1 st x0 = x1 holds f|X0 is_continuous_at x0 implies f|X1
  is_continuous_at x1
proof
  assume
A1: X1 is SubSpace of X0;
  let x0 be Point of X0, x1 be Point of X1;
  assume
A2: x0 = x1;
  assume f|X0 is_continuous_at x0;
  then (f|X0)|X1 is_continuous_at x1 by A1,A2,Th74;
  hence thesis by A1,Th71;
end;
