Attribute Usage
 ===============
 
 Consider attribute assignment observations, along with the possibility of class attribute
 assignment.
 
   Note direct assignments as usual, indirect assignments via the attribute usage
   mechanism. During attribute collection and inference, add assigned values to all
   inferred targets.
 
   Since class attributes can be assigned, StoreAttrIndex would no longer need to reject
   static attributes, although this might still be necessary where attribute usage analysis
   has not been performed.
 
   Potentially consider changing static attribute details to use object-relative offsets in
   order to simplify the instruction implementations. This might allow us to eliminate the
   static attribute flag for attributes in the object table, at least at run-time.
 
 Consider attribute usage observations being suspended inside blocks where AttributeError
 may be caught (although this doesn't anticipate such exceptions being caught outside a
 function altogether).
 
 Consider type deduction and its consequences where types belong to the same hierarchy
 and where a guard could be generated for the most general type.
 
 Consider permitting multiple class alternatives where the attributes are all identical.
 
 Support class attribute positioning similar to instance attribute positioning, potentially
 (for both) based on usage observations. For example, if __iter__ is used on two classes,
 the class attribute could be exposed at a similar relative position to the class (and
 potentially accessible using a LoadAttr-style instruction).
 
 **** Constant attribute users need not maintain usage since they are already resolved. ****
 
 Loop entry points should capture usage to update later assignments in the loop.
 The continue and break statements should affect usage propagation.
 
 Consider handling CallFunc in micropython.inspect in order to produce instances of specific classes.
 Then, consider adding support for guard removal/verification where known instances are involved.
 Consider handling branches of values within namespaces in order to support more precise value usage.
 
 Frame Optimisations
 ===================
 
 Stack frame replacement where a local frame is unused after a call, such as in a tail call
 situation.
 
 Local assignment detection plus frame re-use. Example: slice.__init__ calls
 xrange.__init__ with the same arguments which are unchanged in xrange.__init__. There is
 therefore no need to build a new frame for this call.
 
 Function Specialisation
 =======================
 
 Specialisation of certain functions, such as isinstance(x, cls) where cls is a known
 constant.
 
 Structure and Object Table Optimisations
 ========================================
 
 Fix object table entries for attributes not provided by any known object, or provide an
 error, potentially overridden by options. For example, the augmented assignment methods
 are not supported by the built-in objects and thus the operator module functions cause
 the compilation to fail. Alternatively, just supply the methods since something has to do
 so in the builtins.
 
 Consider attribute merging where many attributes are just aliases for the same underlying
 definition.
 
 Consider references to defaults as occurring only within the context of a particular
 function, thus eliminating default value classes if such functions are not themselves
 invoked.
 
 Scope Handling
 ==============
 
 Consider merging the InspectedModule.store tests with the scope conflict handling.
 
 Consider labelling _scope on assignments and dealing with the assignment of removed
 attributes, possibly removing the entire assignment, and distinguishing between such cases
 and unknown names.
 
 Check name origin where multiple branches could yield multiple scope interpretations:
 
 ----
 try:
     set # built-in name
 except NameError:
     from sets import Set as set # local definition of name
 
 set # could be confused by the local definition at run-time
 ----
 
 Object Coverage
 ===============
 
 Support __init__ traversal (and other implicit names) more effectively.
 
 Other
 =====
 
 Support tuple as a function returning any input tuple uncopied.
 
 Check context_value initialisation (avoiding or handling None effectively).
 
 __getitem__ could be written in Python, using a native method only to access fragments.
 
 Consider better "macro" support where new expressions need to be generated and processed.
 
 Detect TestIdentity results involving constants, potentially optimising status-affected
 instructions:
 
   TestIdentity(x, y) # where x is always y
   JumpIfFalse(...)   # would be removed (never false)
   JumpIfTrue(...)    # changed to Jump(...)
 
 Status-affected blocks could be optimised away for such constant-related results.