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8.1.2 Numeric Functions

The following list describes all of the built-in functions that work with numbers. Optional parameters are enclosed in square brackets ([ ]):

int(x)
This returns the nearest integer to x, located between x and zero and truncated toward zero.

For example, int(3) is 3, int(3.9) is 3, int(-3.9) is −3, and int(-3) is −3 as well.

sqrt(x)
This returns the positive square root of x. gawk reports an error if x is negative. Thus, sqrt(4) is 2.
exp(x)
This returns the exponential of x (e ^ x) or reports an error if x is out of range. The range of values x can have depends on your machine's floating-point representation.
log(x)
This returns the natural logarithm of x, if x is positive; otherwise, it reports an error.
sin(x)
This returns the sine of x, with x in radians.
cos(x)
This returns the cosine of x, with x in radians.
atan2(y, x)
This returns the arctangent of y / x in radians.
rand()
This returns a random number. The values of rand are uniformly distributed between zero and one. The value could be zero but is never one.1

Often random integers are needed instead. Following is a user-defined function that can be used to obtain a random non-negative integer less than n:

          function randint(n) {
               return int(n * rand())
          }
     

The multiplication produces a random number greater than zero and less than n. Using int, this result is made into an integer between zero and n − 1, inclusive.

The following example uses a similar function to produce random integers between one and n. This program prints a new random number for each input record:

          # Function to roll a simulated die.
          function roll(n) { return 1 + int(rand() * n) }
          
          # Roll 3 six-sided dice and
          # print total number of points.
          {
                printf("%d points\n",
                       roll(6)+roll(6)+roll(6))
          }
     

Caution: In most awk implementations, including gawk, rand starts generating numbers from the same starting number, or seed, each time you run awk. Thus, a program generates the same results each time you run it. The numbers are random within one awk run but predictable from run to run. This is convenient for debugging, but if you want a program to do different things each time it is used, you must change the seed to a value that is different in each run. To do this, use srand.

srand([x])
The function srand sets the starting point, or seed, for generating random numbers to the value x.

Each seed value leads to a particular sequence of random numbers.2 Thus, if the seed is set to the same value a second time, the same sequence of random numbers is produced again.

Different awk implementations use different random-number generators internally. Don't expect the same awk program to produce the same series of random numbers when executed by different versions of awk.

If the argument x is omitted, as in `srand()', then the current date and time of day are used for a seed. This is the way to get random numbers that are truly unpredictable.

The return value of srand is the previous seed. This makes it easy to keep track of the seeds in case you need to consistently reproduce sequences of random numbers.


Footnotes

[1] The C version of rand is known to produce fairly poor sequences of random numbers. However, nothing requires that an awk implementation use the C rand to implement the awk version of rand. In fact, gawk uses the BSD random function, which is considerably better than rand, to produce random numbers.

[2] Computer-generated random numbers really are not truly random. They are technically known as “pseudorandom.” This means that while the numbers in a sequence appear to be random, you can in fact generate the same sequence of random numbers over and over again.