2.2 Program Execution

What it means to write and run a Python script depends on whether you look at these tasks as a programmer or as a Python interpreter. Both views offer important perspective on Python programming.

2.2.1 The Programmer's View

In its simplest form, a Python program is just a text file containing Python statements. For example, the following file, named script1.py, is one of the simplest Python scripts we could dream up, but it passes for an official Python program:

print 'hello world' print 2 ** 100

This file contains two Python print statements, which simply print a string (the text in quotes) and a numeric expression result (2 to the power 100) to the output stream. Don't worry about the syntax of this code yet for this chapter, we're interested only in getting it to run. We'll explain the print statement, and why you can raise 2 to the power 100 in Python without overflowing, in later parts of this book.

You can create such a file of statements with any text editor you like. By convention, Python program files are given names that end in ".py"; technically, this naming scheme is required only for files that are "imported," as shown later in this book, but most Python files have .py names for consistency.

After you've typed these statements into a text file in one way or another, you must tell Python to execute the file which simply means to run all the statements from top to bottom in the file, one after another. Python program files may be launched by command lines, by clicking their icons, and with other standard techniques. We'll demonstrate how to invoke this execution in the next chapter. If all goes well, you'll see the results of the two print statements show up somewhere on your computer by default, usually in the same window you were in when you ran the program:

hello world 1267650600228229401496703205376

For example, here's how this script ran from a DOS command line on a Windows laptop, to make sure it didn't have any silly typos:

D:\temp>python script1.py hello world 1267650600228229401496703205376

We've just run a Python script that prints a string and a number. We probably won't win any programming awards with this code, but it's enough to capture the basics of program execution.

2.2.2 Python's View

The brief description of the prior section is fairly standard for scripting languages, and is usually all that most Python programmers need to know. You type code into text files, and run those files through the interpreter. Under the hood, though, a bit more happens when you tell Python to "go." Although knowledge of Python internals is not strictly required for Python programming, a basic understanding of the runtime structure of Python can help you grasp the bigger picture of program execution.

When you instruct Python to run your script, there are a few steps that Python carries out before your code actually starts crunching away. Specifically, it's first compiled to something called byte code, and then routed to something called a virtual machine.

2.2.2.1 Byte code compilation

Internally, and almost completely hidden from you, Python first compiles your source code (the statements in your file) into a format known as byte code . Compilation is simply a translation step, and byte code is a lower-level, and platform-independent, representation of your source code. Roughly, each of your source statements is translated into a group of byte code instructions. This byte code translation is performed to speed execution byte code can be run much quicker than the original source code statements.

You'll notice the prior paragraph said that this is almost completely hidden from you. If the Python process has write-access on your machine, it will store the byte code of your program in files that end with a .pyc extension (".pyc" means compiled ".py" source). You will see these files show up on your computer after you've run a few programs. Python saves byte code like this as a startup speed optimization. The next time you run your program, Python will load the .pyc and skip the compilation step, as long as you haven't changed your source code since the byte code was saved. Python automatically checks the time stamps of source and byte code files to know when it must recompile.

If Python cannot write the byte code files to your machine, your program still works the byte code is generated in memory and simply discarded on program exit.[1] However, because .pyc files speed startup time, you'll want to make sure they are written for larger programs. Byte code files are also one way to ship Python programs Python is happy to run a program if all it can find are .pyc files, even if the original .py source files are absent. (See Section 2.3.3 later in this chapter for another shipping option.)

[1] And strictly speaking, byte code is saved only for files that are imported, not for the top-level file of a program. We'll explore imports in Chapter 3, and again in Part V. Byte code is also never saved for code typed at the interactive prompt, which is described in Chapter 3.

2.2.2.2 Python Virtual Machine (PVM)

Once your program has been compiled to byte code (or the byte code has been loaded from .pyc files), it is shipped off for execution to something generally known as the Python Virtual Machine (PVM, for the more acronym-inclined among you). The PVM sounds more impressive than it is; really, it's just a big loop that iterates through your byte code instructions, one by one, to carry out their operations. The PVM is the runtime engine of Python; it's always present as part of the Python system, and is the component that truly runs your scripts. Technically, it's just the last step of what is called the Python interpreter.

Figure 2-2 illustrates the runtime structure described. Keep in mind that all of this complexity is deliberately hidden to Python programmers. Byte code compilation is automatic, and the PVM is just part of the Python system that you have installed on your machine. Again, programmers simply code and run files of statements.

Figure 2-2. Runtime execution model
figs/lpy2_0202.gif
2.2.2.3 Performance implications

Readers with a background in fully compiled languages such as C and C++ might notice a few differences in the Python model. For one thing, there is usually no build or "make" step in Python work: code runs immediately after it is written. For another, Python byte code is not binary machine code (e.g., instructions for an Intel chip). Byte code is a Python-specific representation.

This is why some Python code may not run as fast as C or C++, as described in Chapter 1 the PVM loop, not the CPU chip, still must interpret the byte code, and byte code instructions require more work than CPU instructions. On the other hand, unlike classic interpreters, there is still a compile step internally Python does not need to reanalyze and reparse each source statement repeatedly. The net effect is that pure Python code runs somewhere between a traditional compiled language, and a traditional interpreted language. See Chapter 1 for more on Python performance.

2.2.2.4 Development implications

Another ramification of Python's execution model is that there is really no distinction between the development and execution environments. That is, the systems that compile and execute your source code are really one in the same. This similarity may have a bit more significance to readers with a background in traditional compiled languages; but in Python, the compiler is always present at runtime, and is part of the system that runs programs.

This makes for a much more rapid development cycle there is no need to precompile and link before execution may begin. Simply type and run the code. This also adds a much more dynamic flavor to the language it is possible, and often very convenient, for Python programs to construct and execute other Python programs at runtime. The eval and exec built-ins, for instance, accept and run strings containing Python program code. This structure is also why Python lends itself to product customization because Python code can be changed on the fly, users can modify the Python parts of a system onsite, without needing to have or compile the entire system's code.



Learning Python
Learning Python: Powerful Object-Oriented Programming
ISBN: 0596158068
EAN: 2147483647
Year: 2003
Pages: 253
Authors: Mark Lutz

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