Macros do code transformations
The macro transforms source code. A lazy evaluation does not. Imagine that you can now write functions which transform arbitrary code to arbitrary different code.
Very simple code transformations
The creation of simple language constructs is also only a very simple example. Consider your example of opening a file:
(with-open-file (stream file :direction :input)
(call-with-stream (function do-something)
What the macro gives me is a slightly different syntax and code structure.
Embedded language: advanced iteration constructs
Next consider a slightly different example:
(loop for i from 10 below 20 collect (sqr i))
(collect-for 10 20 (function sqr))
We can define a function
COLLECT-FOR which does the same for a simple loop and has variables for start, end and a step function.
LOOP provides a new language. The
LOOP macro is a compiler for this language. This compiler can do
LOOP specific optimizations and can also check the syntax at compile time for this new language. An even more powerful loop macro is
ITERATE. These powerful tools on the language level now can be written as libraries without any special compiler support.
Walking the code tree in a macro and making changes
Next another simple example:
(with-slots (age name) some-person
(princ " "
vs. something similar:
(flet ((age (person) (slot-value person 'age))
(name (person) (slot-value person 'name)))
(princ " ")
WITH-SLOTS macro causes the complete walk of the enclosed source tree and replaces the variable name with a call to
(SLOT-VALUE SOME-PERSON 'name):
(print (slot-value some-person 'name))
(princ " "
(princ (slot-value some-person 'age)))
In this case the macro can rewrite selected parts of the code. It understands the structure of the Lisp language and knows that name and age are variables. It also understands that in some situations
age might not be variables and should not be rewritten. This is an application of a so-called Code Walker, a tool that can walk code trees and make changes to the code tree.
Macros can modify the compile-time environment
Another simple example, the contents of a small file:
(defmacro oneplus (x)
(print (list 'expanding 'oneplus 'with x))
(defun example (a b)
(+ (oneplus a) (oneplus (* a b))))
In this example we are not interested in the macro
ONEPLUS, but in the macro
What is interesting about it? In Lisp you can have a file with above contents and use the file compiler to compile that file.
;;; Compiling file /private/tmp/test.lisp ...
;;; Safety = 3, Speed = 1, Space = 1, Float = 1, Interruptible = 1
;;; Compilation speed = 1, Debug = 2, Fixnum safety = 3
;;; Source level debugging is on
;;; Source file recording is on
;;; Cross referencing is on
; (TOP-LEVEL-FORM 0)
(EXPANDING ONEPLUS SOURCE A)
(EXPANDING ONEPLUS SOURCE (* A B))
;; Processing Cross Reference Information
So we see, that the file compiler expands the use of the
What is special about that? There is a macro definition in the file and in the next form we already use that new macro
ONEPLUS. We have never loaded the macro definition into Lisp. Somehow the compiler knows and registers the defined macro
ONEPLUS and is then able to use it.
So the macro
DEFMACRO registers the newly defined macro
ONEPLUS in the compile-time environment, so that the compiler knows about this macro - without loading the code. The macro then can be executed at compile-time during macro expansion.
With a function we can't do that. The compiler creates code for function calls, but does not run them. But a macro can be run at compile time and add 'knowledge' to the compiler. This knowledge then is valid during the run of the compiler and partially forgotten later.
DEFMACRO is a macro which executes at compile time and then informs the compile-time environment of a new macro.
Note also that the macro
ONEPLUS is also run twice, since it is used twice in the file. The side effect is that it prints something. But
ONEPLUS could have also other arbitrary side effects. For example it could check the enclosed source against a rule base and alert you if for example the enclosed code violates some rules (think of a style checker).
That means, that a macro, here
DEFMACRO, can change the language and its environment during compilation of a file. In other languages the compiler might provide special compiler directives which will be recognized during compilation. There are many examples for such defining macros influencing the compiler:
Macros can make the user code shorter
A typical example is the
DEFSTRUCT macro for defining record-like data structures.
(defstruct person name age salary)
defstruct macro creates code for
- a new structure type
person with three slots
- slot accessors for reading and writing the values
- a predicate to check if some object is of class
make-person function to create structure objects
- a printed representation
Additionally it may:
- record the source code
- record the origin of the source code (file, editor buffer, REPL, ...)
- cross-reference the source code
The original code to define the structure is a short line. The expanded code is much longer.
DEFSTRUCT macro does not need access to a meta-level of the language to create these various things. It just transforms a compact piece of descriptive code into the, typically longer, defining code using the typical language constructs.