wizlib 2.0.12

Framework for flexible and powerful command-line applications

WizLib

Framework for flexible and powerful command-line applications

ClassFamily

A class family is a set of class definitions that use single inheritance (each subclass inherits from only one parent) and often multiple inheritance (subclasses can inherit from subclasses). So it's a hierarchy of classes, with one super-parent (termed the "atriarch") at the top.

We offer a way for members of the family to declare themselves simply by living in the right package location. Then those classes can be instantiated using keys or names, without having to be specifically called. The members act independently of each other.

What we get, after importing everything and loading it all, is essentially a little database of classes, where class-level properties become keys for looking up member classes. So, for example, we can have a family of commands, and use a command string to look up the right command.

Ultimately, the atriarch of the family -- the class at the top of the hierarchy -- holds the database, actually a list, in the property called "family". So that class can be queried to find appropriate family member classes or instances thereof.

This utility provides functions for importing family members, loading the "families" property of the super-parent, and querying the family.

In the process of loading and querying the class family, we need to avoid inheritance of attributes. There might be abstract intermediary classes that don't want to play. So we use __dict__ to ensure we're only seeing the atttributes that are defined on that specific class.

SuperWrapper

Provide a decorator to wrap a method so that it's called within the inherited version of that method.

Example of use:

class Parent(SuperWrapper):
    def execute(self, method, *args, **kwargs):
        print(f"Parent execute before")
        method(self, *args, **kwargs)
        print(f"Parent execute after")

class InBetween(Parent):
    @Parent.wrap
    def execute(self, method, *args, **kwargs):
        print(f"IB execute before")
        method(self, *args, **kwargs)
        print(f"IB execute after")

class NewChild(InBetween):
    @InBetween.wrap
    def execute(self, name):
        print(f"Hello {name}")

c = NewChild()
c.execute("Jane")

Note that for a method to be "wrappable" it must take the form shown above, and explicitly call the method that's handed into it. So strictly, this is different from regular inheritance, where the parent class method has the same signature as the child class method.

RLInput

Python supports the GNU readline approach, which enables tab completion, key mappings, and history with the input() function. But the documentation is cryptic, and the implementation differs between Linux and MacOS. RLInput makes it easy.

from wizlib.rlinput import rlinput

It's just a function, with up to three parameters:

• intro:str="" - The intro or prompt, same as in the input() function.
• default:str="" - If provided, the text will be inserted into the buffer at the start, with the cursor at the end of the buffer. So that becomes the default, that must be overridden by the user if they want different input.
• options:list=[] - A list of options for tab completion. This assumes the options are choices for the entire entry; it's not context-dependent within the buffer.

Emacs keys are enabled by default; I'm able to use the arrow keys on my Mac so you should too. I made one change to the keyboard mappings, which is the Ctrl-A, instead of just moving the cursor to the beginning of the line, wipes the entire buffer. So to wipe out the default value and type or tab something new, just hit Ctrl-A.

The WizApp framework

Docs in progress - might be out of date

Commands automatically handle input via stdin for non-tty inputs such as pipes. Some details:

• The argument name is input
• Therefore input is a reserved name for arguments
• Optionally use the --input or -i command line argument to pass in the same information
• Reading from stdin in tty cases (i.e. in the terminal) would still have to happen in the command itself.

ConfigHandler

Enables easy configuration across multiple levels. Tries each of the following approaches in order until one finds the required config option

• First look for attributes of the instance (subclass of ConfigHandler) itself (e.g. gitlab_host)
• Then look for a specific env variable for that config setting in all caps, e.g. GITLAB_HOST
• If those both fail, then look for a YAML configuration file:
  • First identified with a --config / -c option on the command line
  • Then with a path in the APPNAME_CONFIG environment variable - note all caps
  • Then look in the local working directory for .appname.yml
  • Then look for ~/.appname.yml in the user's home directory

Config files are in YAML, and look something like this:

gitlab:
  host: gitlab.com
local:
  root: $HOME/git

Note that nested labels in the config map to hyphenated command line options.

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