It depends on the specs of your charge controller. A good MPPT controller might be able to take 80 V x 6 A input (480 W), and turn it into 12 V x 40 A output (480 W) (less 5-10% conversion losses). However, there are some knock-off charge controllers out there that are labeled MPPT, but are in fact purely PWM. With PWM, your amps in = amps out, so you are better off keeping the array voltage closer to the battery voltage and the amps as high as possible. Since even 12 V panels typically operate at about 17 V (subject to temperature, hard shade, and other considerations), PWM losses can be high, 20% or worse. (There are also true MPPT controllers out there that just have a very small voltage range... helping efficiency somewhat relative to PWM, but not offering the advantages of series wiring for the panels)

The input voltage rating of your charge controller could be a good clue as to how it actually operates, if you are unsure. If your controller really says dc input must be 12 or 24 V, then parallel is probably your only choice, and there is a chance that it isn't actually MPPT at all.

You are confusing CC input here
If you are certain that your controller is a true 40a mppt it must have at least 70v pv input . Those you mention above are battery voltage to the controller . The controller can take a higher input from pv and convert it to the appropriate battery voltage.

But, if as noted in another thread, you have already purchased a 12V inverter and do not want to exchange it for a 24V model, you are stuck.
With a suitable MPPT controller you could still put all of the panels in series to charge a 12V battery bank.
With a PMW CC you are committed to parallel panels.

What are you trying to do here? Have you already bought the inverter? Lots of unanswered questions.

Provided you have a good CC, wiring all 4 panels in series would eliminate the need for string breakers and reduce cost of the wire since you would raise the voltage and lower the current. I.E. (I'm assuming you have 100W "battery" panels which are 17V 8A) all 4 in series would be 60ish volts and 8 Amps so you could run a smaller ga wire to the CC (length of run will affect required conductor size), in parallel you would have 17V but 32A which requires a more expensive conductor.
For your batteries, batteries configured into 1 series string is your best option for ease of maintenance and battery life as an equal amount of current must flow through all batteries.

edit: you were replying to sensi while I was writing this, disregard unless you plan to buy different CC

Parallel or Series-Parallel

Thank you, Sensij, for your reply. My controller can handle 12 or 24 volt input but I am wiring the panels as all four in parallel because I have 12-volt batteries (parallel) and a Nature Power 2000W pure sine wave inverter. I know I can wire the batteries series-parallel for 24 volts but I thought the inverter needs 12V DC input. Am I incorrect?

Parallel or Series-Parallel?

Thank you, Amy, for your reply. I'm curious if you have an opinion regarding the reply from Sensij which asks why all four parallel instead of series-parallel or four in series. I am wiring the panels as all four in parallel because I have four 12-volt batteries (parallel) and I assumed 24 volts is not right with these batteries. What do you think?

One of the parameters on the typical panel label is the maximum series fuse size. When you have three or more panels or strings of panels in parallel, each string must have a fuse no larger than that specified (typically between 1-1/2 and 2 times the rated Isc.)

With an MPPT charge controller, why would you have those four panels in parallel (unless they are oriented different directions)? For most true MPPT controllers, you could probably pair the panels and put the two pairs in parallel, or with the better CC's, go all four in series.

But the single pair of wires from the combiner box to the CC will need to handle 40A and that wire should be protected by a 40A over current device.

Use a Combiner box with breaker for each panel, like Midnite Solar PV6. Short circuit current of panel (Isc) x 1.56. Probably around 6.06Isc x 1.56 = 9.45A, round up to 10A breakers.