In theory. But in practice the first sequence would indicate a higher probability of an unfair coin than the second sequence.
I'll elaborate more later, but my position is that the statement you're responding to is inherently flawed.
The real question we need to be dealing with is this: Given a supposedly fair toss, is a completely smooth results-space more or less likely to indicate cheating than is a non-smooth results-space (regardless of the exact configuration of the non-smooth space)?
By analogy, let us consider the task of determining whether we are in the ocean or a swimming pool by means of examining the behavior of the water within a nearby radius.
If we detect low turbulence and no tidal effect, then we are either in a swimming pool, or in an unusually stable sector of ocean.
Suppose that the circumstances do not change over the course of 2 hours.
Assuming that we know we are somewhere in the real world, do we conclude that we might be in the middle of an unprecedented anomaly, or that we're in a swimming pool?
If we listen to the logic of the post you're responding to, we simply count the "extremly unlikely" low-turbulence/no-tide scenario as one of a large number of equally unlikely possible configurations.
But if we use our faculties of reason, we will realize that there are a large number of configurations that conform to "we are in the ocean" and a much smaller number of configurations that conform to "we're in a pool".
So this business of claiming that a run of 100 heads is equally un/likely as any particular scenario of mixed tails and heads is a red herring.
The important feature to recognize is that a vast number of mixed heads/tails configurations will be typical of the results-space of a long series of fair coin tosses, while a long series of only heads or tails is typical only of a rigged system.
The appeal to the supposed equal likelihood of any one particular configuration is a misapplication of statistics to the actual situation on the ground.
