I'm reading SICP too, and I've been curious by the definition of normal order given by the authors. It seemed rather similar to Lazy evaluation to me, so I went looking for some more information regarding both.
I know this question was asked a long time ago, but I looked at the FAQ and found no mention of answering old questions, so I thought I'd leave what I've found here so other people could use it in the future.
This is what I've found, and I'm inclined to agree with those:
I would argue (as have others) that lazy evaluation and
NormalOrderEvaluation are two different things; the difference is
alluded to above. In lazy evaluation, evaluation of the argument is
deferred until it is needed, at which point the argument is evaluated
and its result saved (memoized). Further uses of the argument in the
function use the computed value. The C/C++ operators ||, &&, and ? :
are both examples of lazy evaluation. (Unless some newbie C/C++
programmer is daft enough to overload && or ||, in which case the
overloaded versions are evaluated in strict order; which is why the &&
and || operators should NEVER be overloaded in C++).
In other words, each argument is evaluated at most once, possibly not
NormalOrderEvaluation, on the other hand, re-evaluates the expression
each time it is used. Think of C macros, CallByName in languages which
support it, and the semantics of looping control structures, etc.
Normal-order evaluation can take much longer than applicative order
evaluation, and can cause side effects to happen more than once.
(Which is why, of course, statements with side effects generally ought
not be given as arguments to macros in C/C++)
If the argument is invariant and has no side effects, the only
difference between the two is performance. Indeed, in a purely
functional language, lazy eval can be viewed as an optimization of
normal-order evaluation. With side effects present, or expressions
which can return a different value when re-evaluated, the two have
different behavior; normal order eval in particular has a bad
reputation in procedural languages due to the difficulty of reasoning
about such programs without ReferentialTransparency
Should also be noted that strict-order evaluation (as well as lazy
evaluation) can be achieved in a language which supports normal-order
evaluation via explicit memoing. The opposite isn't true; it requires
passing in thunks, functions, or objects which can be called/messaged
in order to defer/repeat the evaluation.
Lazy evaluation combines normal-order evaluation and sharing:
• Never evaluate something until you have to (normal-order)
• Never evaluate something more than once (sharing)