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<h1>femtoLisp</h1>
<hr>
femtoLisp is an elegant Lisp implementation. Its goal is to be a
reasonably efficient and capable interpreter with the shortest, simplest
code possible. As its name implies, it is small (10<sup>-15</sup>).
Right now it is just 1000 lines of C (give or take). It would make a great
teaching example, or a useful system anywhere a very small Lisp is wanted.
It is also a useful basis for developing other interpreters or related
languages.
<h2>The language implemented</h2>
femtoLisp tries to be a generic, simple Lisp dialect, influenced by McCarthy's
original.
<ul>
<li>Types: cons, symbol, 30-bit integer, builtin function
<li>Self-evaluating lambda, macro, and label forms
<li>Full Common Lisp-style macros
<li>Case-sensitive symbol names
<li>Scheme-style evaluation rule where any expression may appear in head
position as long as it evaluates to a callable
<li>Scheme-style formal argument lists (dotted lists for varargs)
<li>Transparent closure representation <tt>(lambda args body . env)</tt>
<li>A lambda body may contain only one form. Use explicit <tt>progn</tt> for
multiple forms. Included macros, however, allow <tt>defun</tt>,
<tt>let</tt>, etc. to accept multiple body forms.
<li>Builtin function names are constants and cannot be redefined.
<li>Symbols have one binding, as in Scheme.
</ul>
<b>Builtin special forms:</b><br>
<tt>quote, cond, if, and, or, lambda, macro, label, while, progn, prog1</tt>
<p>
<b>Builtin functions:</b><br>
<tt>eq, atom, not, symbolp, numberp, boundp, cons, car, cdr,
read, eval, print, load, set,
+, -, *, /, &lt;, apply, rplaca, rplacd</tt>
<p>
<b>Included library functions and macros:</b><br>
<tt>
setq, setf, defmacro, defun, define, let, let*, labels, dotimes,
macroexpand-1, macroexpand, backquote,
null, consp, builtinp, self-evaluating-p, listp, eql, equal, every, any,
when, unless,
=, !=, &gt;, &lt;=, &gt;=, compare, mod, abs, identity,
list, list*, length, last, nthcdr, lastcdr, list-ref, reverse, nreverse,
assoc, member, append, nconc, copy-list, copy-tree, revappend, nreconc,
mapcar, filter, reduce, map-int,
symbol-plist, set-symbol-plist, put, get
</tt>
<p>
<a href="system.lsp">system.lsp</a>
<h2>The implementation</h2>
<ul>
<li>Compacting copying garbage collector (<tt>O(1)</tt> in number of dead
objects)
<li>Tagged pointers for efficient type checking and fast integers
<li>Tail-recursive evaluator (tail calls use no stack space)
<li>Minimally-consing <tt>apply</tt>
<li>Interactive and script execution modes
</ul>
<p>
<a href="lisp.c">lisp.c</a>
<h2>femtoLisp2</h2>
This version includes robust reading and printing capabilities for
circular structures and escaped symbol names. It adds read and print support
for the Common Lisp read-macros <tt>#., #n#,</tt> and <tt>#n=</tt>.
This allows builtins to be printed in a readable fashion as e.g.
"<tt>#.eq</tt>".
<p>
The net result is that the interpreter achieves a highly satisfying property
of closure under I/O. In other words, every representable Lisp value can be
read and printed.
<p>
The traditional builtin <tt>label</tt> provides a purely-functional,
non-circular way
to write an anonymous recursive function. In femtoLisp2 you can
achieve the same effect "manually" using nothing more than the reader:
<br>
<tt>#0=(lambda (x) (if (&lt;= x 0) 1 (* x (#0# (- x 1)))))</tt>
<p>
femtoLisp2 has the following extra features and optimizations:
<ul>
<li> builtin functions <tt>error, exit,</tt> and <tt>princ</tt>
<li> read support for backquote expressions
<li> delayed environment consing
<li> collective allocation of cons chains
</ul>
Those two optimizations are a Big Deal.
<p>
<a href="lisp2.c">lisp2.c</a> (uses <a href="flutils.c">flutils.c</a>)
<h2>Performance</h2>
femtoLisp's performance is surprising. It is faster than most
interpreters, and it is usually within a factor of 2-5 of compiled CLISP.
<table border=1>
<tr>
<td colspan=3><center><b>solve 5 queens problem 100x</b></center></td>
<tr>
<td> <td>interpreted<td>compiled
<tr>
<td>CLISP <td>4.02 sec <td>0.68 sec
<tr>
<td>femtoLisp2<td>2.62 sec <td>2.03 sec**
<tr>
<td>femtoLisp <td>6.02 sec <td>5.64 sec**
<tr>
<td colspan=3><center><b>recursive fib(34)</b></center></td>
<tr>
<td> <td>interpreted<td>compiled
<tr>
<td>CLISP <td>23.12 sec <td>4.04 sec
<tr>
<td>femtoLisp2<td>4.71 sec <td>n/a
<tr>
<td>femtoLisp <td>7.25 sec <td>n/a
<tr>
</table>
** femtoLisp is not a compiler; in this context "compiled" means macros
were pre-expanded.
<h2>"Installation"</h2>
Here is a <a href="Makefile">Makefile</a>. Type <tt>make</tt> to build
femtoLisp, <tt>make NAME=lisp2</tt> to build femtoLisp2.
<h2>Tail recursion</h2>
The femtoLisp evaluator is tail-recursive, following the idea in
<a href="http://library.readscheme.org/servlets/cite.ss?pattern=Ste-76b">
Lambda: The Ultimate Declarative</a> (should be required reading
for all schoolchildren).
<p>
The femtoLisp source provides a simple concrete example showing why a function
call is best viewed as a "renaming plus goto" rather than as a set of stack
operations.
<p>
Here is the non-tail-recursive evaluator code to evaluate the body of a
lambda (function), from <a href="lisp-nontail.c">lisp-nontail.c</a>:
<pre>
PUSH(*lenv); // preserve environment on stack
lenv = &amp;Stack[SP-1];
v = eval(*body, lenv);
POP();
return v;
</pre>
(Note that because of the copying garbage collector, values are referenced
through relocatable handles.)
<p>
Superficially, the call to <tt>eval</tt> is not a tail call, because work
remains after it returns&mdash;namely, popping the environment off the stack.
In other words, the control stack must be saved and restored to allow us to
eventually restore the environment stack. However, restoring the environment
stack is the <i>only</i> work to be done. Yet after this point the old
environment is not used! So restoring the environment stack isn't
necessary, therefore restoring the control stack isn't either.
<p>
This perspective makes proper tail recursion seem like more than an
alternate design or optimization. It seems more correct.
<p>
Here is the corrected, tail-recursive version of the code:
<pre>
SP = saveSP; // restore stack completely
e = *body; // reassign arguments
*penv = *lenv;
goto eval_top;
</pre>
<tt>penv</tt> is a pointer to the old environment, which we overwrite.
(Notice that the variable <tt>penv</tt> does not even appear in the first code
example.)
So where is the environment saved and restored, if not here? The answer
is that the burden is shifted to the caller; a caller to <tt>eval</tt> must
expect that its environment might be overwritten, and take steps to save it
if it will be needed further after the call. In practice, this means
the environment is saved and restored around the evaluation of
arguments, rather than around function applications. Hence <tt>(f x)</tt>
might be a tail call to <tt>f</tt>, but <tt>(+ y (f x))</tt> is not.
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