It is a tradeoff.
A 32 bit signed integer can express every integer between -231 and +231-1.
A 32 bit float uses exponential notation and can express a much wider range of numbers, but would be unable to express all of the numbers in the range -- not even all of the integers. It uses some of the bits to represent a fraction, and the rest to represent an exponent. It is effectively the binary equivalent of a notation like 6.023*1023 or what have you, with the distance between representable numbers quite large at the ends of the range.
For more information, I would read this article, "What Every Computer Scientist Should Know About Floating Point Arithmetic" by David Goldberg: http://web.cse.msu.edu/~cse320/Documents/FloatingPoint.pdf
By the way, on your platform, I would expect a float to be a 32 bit quantity and a long to be a 64 bit quantity, but that isn't really germane to the overall point.
Performance is kind of hard to define here. Floating point operations may or may not take significantly longer than integer operations depending on the nature of the operations and whether hardware acceleration is used for them. Typically, operations like addition and subtraction are much faster in integer -- multiplication and division less so. At one point, people trying to bum every cycle out when doing computation would represent real numbers as "fixed point" arithmetic and use integers to represent them, but that sort of trick is much rarer now. (On an Opteron, such as you are using, floating point arithmetic is indeed hardware accelerated.)
Almost all platforms that C runs on have distinct "float" and "double" representations, with "double" floats being double precision, that is, a representation that occupies twice as many bits. In addition to the space tradeoff, operations on these are often somewhat slower, and again, people highly concerned about performance will try to use floats if the precision of their calculation does not demand doubles.