Solving problems with Python

From AstroEd

Revision as of 06:02, 21 February 2018 by WikiSysop (talk | contribs)

Now with many useful tools in hand from our short course on using Python in Physics and Astronomy, let us see how to make them work together to solve problems.

Flow control

The if statement is fundamental to making decisions within a program. It works simply

if x > 0.:
  y = 1./x
elif x < -1.:
elif x == 0:
  print 'Cannot divide by zero.'
  y = 1./x
z = y

Notice that indentation (by any fixed number of spaces) is used to separate the functions within the statement, and that each branch is defined by a :. The end of a branch occurs when the indentation goes back to the previous level. Each decision is based on a logical boolean value such as (x > 0.), which is True when x is greater than 0. and False otherwise. Within the if processing, a pass is a way to do nothing, and an exit() leaves the entire program.

A while statement tests whether its argument is true, and sets up a loop that continues as long as it is. The program

flag = True
x = 0.
while flag:
  x = x + 1.
  if x > 10.:
    flag = False
print x

increases x until it is 11. and then prints the value.

Loops such as this may include a try block. This enables handling an exception, such as in this program to calculate x2 with input from keyboard.

while True:
    x = int(raw_input("Please enter a number: "))
  except ValueError:
    print "Oops!  That was no valid number.  Try again..."
print y

Here a break exits the loop from the try block unless an exception is thrown. A while statement can also test for something that is changed in the loop.


Within a Python program you can define your own functions. Here's one to take an angle in degrees and reduce it to an angle between 0 and 360.

def map360(angle):
  if (angle < 0.0):   
    n = int(angle / 360.0) - 1
    return (angle - float(n) * 360.0)
  elif (angle >= 360.0):  
    n = int(angle / 360.0)
    return (angle - float(n) * 360.0)
    return (angle)

Functions may have any number of objects as arguments, of any data type. Once defined, you may use a function anywhere in a program.


The while loop makes repeated passes through a block of code as long as a test condition is satisfied. This allows us to make sequential changes to achieve a desired outcome, such as evaluating a series until the error is acceptable, or fitting data until the fitting errors are minimized. Python also has several built-in ways to manage interation, and the most useful is the for loop.

idata = range(10)
print idata
fdata = [-1.]
for x in idata:
  f = float(x)**2.0
  print fdata

generates this output

[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]
[-1.0, 0.0]
[-1.0, 0.0, 1.0]
[-1.0, 0.0, 1.0, 4.0]
[-1.0, 0.0, 1.0, 4.0, 9.0]
[-1.0, 0.0, 1.0, 4.0, 9.0, 16.0]
[-1.0, 0.0, 1.0, 4.0, 9.0, 16.0, 25.0]
[-1.0, 0.0, 1.0, 4.0, 9.0, 16.0, 25.0, 36.0]
[-1.0, 0.0, 1.0, 4.0, 9.0, 16.0, 25.0, 36.0, 49.0]
[-1.0, 0.0, 1.0, 4.0, 9.0, 16.0, 25.0, 36.0, 49.0, 64.0]
[-1.0, 0.0, 1.0, 4.0, 9.0, 16.0, 25.0, 36.0, 49.0, 64.0, 81.0]

In the first line, range(10) creates a list with values from 0 to 9 which is the first line of the output. We also made a floating point list with one value of -1. to start things off. The for loop interated the idata list, and for each element (now labeled x) we calculated x2.0 and appended it to the fdata floating point list. Inside the iterative loop we printed the list as it grew.

Lists and strings are iterable, and so are dictionaries and even files. An example of iterating a dictionary through a list of its keys would be

messier = {'1' : 'planetary nebula', '2' : 'globular cluster', '51' : 'spiral galaxy' }
for key in messier.keys():
  if messier[key] == 'spiral galaxy':
    print key, messier[key]

which will print

51 spiral galaxy

However, dictionaries can be interated for both key and value by looking at the full list of items.

messier = {'1' : 'planetary nebula', '2' : 'globular cluster', '51' : 'spiral galaxy' }
for key, value in messier.items():
  if value == 'spiral galaxy':
    print key, value

The readline() function for a file iterates line by line through the file, and

myfile = open('catalog.dat')
while True:
  myline = myfile.readline()   
  if not myline:
  print myline

prints lines from catalog.dat. The simpler

for myline in open('catalog.dat'):
  print myline

uses the iterative for loop to print lines from the file one by one as read. You can also open a file and read all the lines as a list and the iteration is hidden.

myfile = open('catalog.dat')
mydata = myfile.readlines()

Iterables and generators

While on the topic of iteration, it is a good moment to explain the ideas of iterables and generators too. The following is nearly verbatim from an excellent reply found on Stackoverflow, a really useful resource when you are lost.

When you create a list, you can read its items one by one. Reading its items one by one is called iteration. In Python 3 you would have

 mylist = [1, 2, 3]
 for i in mylist:

Here "mylist" is iterable. Everything you can use a statment such "for... in..." on is an iterable. This includes lists, strings, and files. When you use a technique called "list comprehension" you can create a list in one line

 mylist = [x*x for x in range(4)]

and see what you have by printing it one element at a time as we did above.

 for i in mylist:

This also shows how the "range(4)" function starts at 0 and ends at 3 in steps of 1.

Iterables store their values in memory, and if you have a lot of values you might not want that. Generators are an interator that generates values as you go this way:

 mygenerator = (x*x for x in range(3))
 for i in mygenerator:

The difference in syntax is the use if ( rather than [. However you cannot ask "for i in mygenerator" more than once.

When defining a function to create a generator, you would use "yield" rather than "return"

 def createGenerator():
   mylist = range(3)
   for i in mylist:
     yield i*i
 mygenerator = createGenerator()  # create a generator
 print(mygenerator)                         # mygenerator is an object!
 for i in mygenerator:


This example could be modified to return a huge set of values, but only once. The "mygenerator" code returns the generator object, and it is run each time "for" uses the generator. The first time the "for" calls the generator object created from your function, it will run the code in your function from the beginning until it hits yield, then it will return the first value of the loop. Then, each other call will run the loop you have written in the function one more time, and return the next value, until there is no value to return. The generator is considered empty once the function runs but does not hit yield anymore. This can happen if the loop comes to an end, or if it does not you do not satisfy another condition.


For examples of Python illustrating flow control, functions, and iteration, see the examples section.


For the assigned homework to use these ideas, see the assignments section.