Uniform access principle


The uniform access principle of computer programming was put forth by Bertrand Meyer. It states "All services offered by a module should be available through a uniform notation, which does not betray whether they are implemented through storage or through computation". This principle applies generally to the syntax of object-oriented programming languages. In simpler form, it states that there should be no syntactical difference between working with an attribute, pre-computed property, or method/query of an object.
While most examples focus on the "read" aspect of the principle, Meyer shows that the "write" implications of the principle are harder to deal with in his monthly column on the Eiffel programming language official website.

Explanation

The problem being addressed by Meyer involves the maintenance of large software projects or software libraries. Sometimes when developing or maintaining software it is necessary, after much code is in place, to change a class or object in a way that transforms what was simply an attribute access into a method call. Programming languages often use different syntax for attribute access and invoking a method,. The syntax change would require, in popular programming languages of the day, changing the source code in all the places where the attribute was used. This might require changing source code in many different locations throughout a very large volume of source code. Or worse, if the change is in an object library used by hundreds of customers, each of those customers would have to find and change all the places the attribute was used in their own code and recompile their programs.
Going the reverse way really was not a problem, as one can always just keep the function and have it simply return the attribute value.
Meyer recognized the need for software developers to write code in such a way as to minimize or eliminate cascading changes in code that result from changes which convert an object attribute to a method call or vice versa. For this he developed the Uniform Access Principle.
Many programming languages do not strictly support the UAP but do support forms of it. Properties, which are provided in a number of programming languages, address the problem Meyer was addressing with his UAP in a different way. Instead of providing a single uniform notation, properties provide a way to invoke a method of an object while using the same notation as is used for attribute access. The separate method invocation syntax is still available.

UAP example

If the language uses the method invocation syntax it may look something like this.

// Assume print displays the variable passed to it, with or without parens
// Set Foo's attribute 'bar' to value 5.
Foo.bar
print Foo.bar

When executed, should display :


Whether or not invokes a function or simply sets an attribute is hidden from the caller.
Likewise whether simply retrieves the value of the attribute, or invokes a function
to compute the value returned, is an implementation detail hidden from the caller.
If the language uses the attribute syntax the syntax may look like this.

Foo.bar = 5
print Foo.bar

Again, whether or not a method is invoked, or the value is simply assigned to an attribute is hidden
from the calling method.

Problems

However, UAP itself can lead to problems, if used in places where the differences between access methods are not negligible, such as when the returned value is expensive to compute or will trigger cache operations.

Language examples

Ruby

Consider the following

y = Egg.new
y.color = "White"
puts y.color

Now the Egg class could be defined as follows

class Egg
attr_accessor :color
def initialize
@color = color
end
end

The above initial code segment would work fine with the Egg being defined as such. The Egg
class could also be defined as below, where color is instead a method. The calling code would
still work, unchanged if Egg were to be defined as follows.

class Egg

def initialize
@rgb_color = to_rgb
end
def color
to_color_name
end
def color=
@rgb_color = to_rgb
end
private
def to_rgb
.....
end
def to_color_name
....
end
end

Note how even though color looks like an attribute in one case and a pair of methods
in the next, the interface to the class remains the same. The person maintaining the Egg class can switch from one form to the other without fear of breaking any caller's code.
Ruby follows the revised UAP, the attr_accessor :color only acts as syntactic sugar for generating accessor/setter methods for color. There is no way in Ruby to retrieve an instance variable from an object without calling a method on it.
Strictly speaking, Ruby does not follow Meyer's original UAP in that the syntax for accessing an attribute is different from the syntax for invoking a method. But here, the access for an attribute will always actually be through a function which is often automatically generated. So in essence, either type of access invokes a function and the language does follow Meyer's revised Uniform Access Principle.

Python

may be used to allow a method
to be invoked with the same syntax as accessing an attribute. Whereas Meyer's UAP would have
a single notation for both attribute access and method invocation,
a language with support for properties still supports separate notations for attribute
and method access. Properties allow the attribute notation to be used, but to hide the
fact that a method is being invoked instead of simply retrieving or setting a value.
As such, Python leaves the option of adherence to UAP up to the individual programmer. The built-in function provides a simple way to decorate any given method in attribute access syntax, thus abstracting away the syntactical difference between method invocations and attribute accesses.
In Python, we may have code that access an object that could be defined such that weight and color are simple attributes as in the following


>>> egg = Egg
>>> egg.color = "green"
>>> print
Egg

class Egg:
def __init__ -> None:
self.weight = weight
self.color = color
def __str__ -> str:
return f''

Or the Egg object could use properties, and invoke getter and setter methods instead

  1. ......
class Egg:
def __init__ -> None:
self.weight = weight_oz
self.color = color_name

@property
def color -> str:
Color of the Egg
return to_color_str
@color.setter
def color -> None:
self._color_rgb = to_rgb
@property
def weight -> float:
Weight in Ounces
return self._weight_gram / 29.3
@weight.setter
def weight -> None:
self._weight_gram = 29.3 * weight_oz
#......


import webcolors
  1. class Egg:
def to_color_str -> str:
try:
return webcolors.rgb_to_name
except ValueError:
return webcolors.rgb_to_hex

def to_rgb -> webcolors.IntegerRGB:
try:
return webcolors.name_to_rgb
except ValueError:
return webcolors.hex_to_rgb
if __name__ "__main__":
import doctest
doctest.testmod

Regardless of which way is defined, the calling code can remain the same. The implementation of can switch from one form to the other without affecting code that uses the Egg class. Languages which implement the UAP have this property as well.

C#

The C# language supports class properties, which provide a means to define and operations for a member variable. The syntax to access or modify the property is the same as accessing any other class member variable, but the actual implementation for doing so can be defined as either a simple read/write access or as functional code.

public class Foo

In the example above, class contains two properties, and. The property is an integer that can be read and written. Similarly, the property is a string that can also be read and modified, but its value is stored in a separate class variable.
Omitting the operation in a property definition makes the property read-only, while omitting the operation makes it write-only.
Use of the properties employs the UAP, as shown in the code below.

public Foo CreateFoo

C++

has neither the UAP nor properties, when an object is changed such that an attribute becomes a pair of functions. Any place in that uses an instance of the object and either sets or gets the attribute value must be changed to invoke one of the functions.. Using templates and operator overloading, it is possible to fake properties, but this is more complex than in languages which directly support properties. This complicates maintenance of C++ programs. Distributed libraries of C++ objects must be careful about how they provide access to member data.

JavaScript

JavaScript has had support for computed properties since 2009.

Next Generation Shell

In Next Generation Shell, accessing object fields is done through the . syntax, similar to other programming languages. Consistent with the rest of the language, the syntax is a shortcut for invoking a method. myobj.myfield is interpreted as a call to method . with arguments myobj and myfield.
The built-in implementation of . returns the value of the field from the memory location dedicated exclusively to the given field of the specific object instance. To customize the behaviour of . for a particular type, one should define a method named . for that type.
Similarly, .= method is called for myobj.myfield = myval syntax.
The following example demonstrates default behavior of the . and .= methods.

type Egg
F init
e = Egg
e.color = "White"
echo

The following example demonstrates customized behavior of the . and .= methods. The code implements accessor for the color field.

type Egg
F init
F.
F.=
e = Egg
e.color = "White"
echo