Stars do not get hot because of nuclear fusion, they become hot enough to sustain nuclear fusion and this process maintains their temperatures. Nuclear fusion actually stops a star getting hotter.
Protostars (before nuclear fusion) get hot because of a well known statistical relationship between the gravitational potential energy of a gas and the internal kinetic energy of the particles that make up the gas. [In an ideal gas, the kinetic energy of the particles is directly proportional to the temperature of the gas.] This is known as the virial theorem, which says that twice the summed kinetic energy of particles ($K$) plus the gravitational potential energy ($Omega$, which is a negative quantity for a bound object) equals zero.
$$ 2K + Omega = 0$$
Now you can write down the total energy of the system as
$$ E_{tot} = K + Omega$$
and hence from the virial theorem that
$$E_{tot} = frac{Omega}{2},$$
which is also negative.
If we now remove energy from the system, for instance by allowing the gas to radiate away energy, such that $Delta E_{tot}$ is negative, then we see that
$$Delta E_{tot} = frac{1}{2} Delta Omega$$
So $Omega$ becomes more negative - which is another way of saying that the protostar attains a more collapsed configuration.
Oddly, at the same time, we can use the virial theorem to see that
$$ Delta K = -frac{1}{2} Delta Omega = -Delta E_{tot}$$
is positive. i.e. the kinetic energies of particles in the gas (and hence their temperatures) actually become hotter. In other words, the gas has a negative heat capacity. But a hotter temperature usually means more radiation is produced and if the energy losses continue, then so does the collapse.
This process is ultimately arrested in a star by the onset of nuclear fusion. This replaces the radiative losses with nuclear energy and the star attains a quasi-equilibrium that lasts as long as it has nuclear fuel to burn.
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