- ; basic list accessors
-
-
-(setq cadr (lambda (l) (car (cdr l))))
-(setq caddr (lambda (l) (car (cdr (cdr l)))))
-(setq list (lexpr (l) l))
-
- ; evaluate a list of sexprs
-
-;(setq progn (lexpr (l) (last l)))
-
+;
+; Copyright © 2016 Keith Packard <keithp@keithp.com>
+;
+; This program is free software; you can redistribute it and/or modify
+; it under the terms of the GNU General Public License as published by
+; the Free Software Foundation, either version 2 of the License, or
+; (at your option) any later version.
+;
+; This program is distributed in the hope that it will be useful, but
+; WITHOUT ANY WARRANTY; without even the implied warranty of
+; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
+; General Public License for more details.
+;
+; Lisp code placed in ROM
+
+ ; return a list containing all of the arguments
+
+(set (quote list) (lexpr (l) l))
;
; Define a variable without returning the value
; having lots of output generated
;
-(setq def (macro (def-param)
+(setq def (macro (name val rest)
(list
'progn
(list
'set
- (list
- 'quote
- (car def-param))
- (cadr def-param)
- )
+ (list 'quote name)
+ val)
+ (list 'quote name)
+ )
+ )
+ )
+
+ ;
+ ; A slightly more convenient form
+ ; for defining lambdas.
+ ;
+ ; (defun <name> (<params>) s-exprs)
+ ;
+
+(def defun (macro (name args exprs)
(list
- 'quote
- (car def-param)
+ def
+ name
+ (list
+ 'lambda
+ args
+ (cond ((cdr exprs)
+ (cons progn exprs))
+ ((car exprs))
+ )
+ )
)
)
+ )
+ ; basic list accessors
+
+
+(defun cadr (l) (car (cdr l)))
+
+(defun caddr (l) (car (cdr (cdr l))))
+
+(defun nth (list n)
+ (cond ((= n 0) (car list))
+ ((nth (cdr list) (1- n)))
+ )
+ )
+
+ ; simple math operators
+
+(defun 1+ (x) (+ x 1))
+(defun 1- (x) (- x 1))
+
+ ; boolean operators
+
+(def or (lexpr (l)
+ (let ((ret nil))
+ (while l
+ (cond ((setq ret (car l))
+ (setq l nil))
+ ((setq l (cdr l)))))
+ ret
)
+ )
+ )
+
+(def and (lexpr (l)
+ (let ((ret t))
+ (while l
+ (cond ((setq ret (car l))
+ (setq l (cdr l)))
+ ((setq ret (setq l nil)))
+ )
+ )
+ ret
+ )
+ )
)
; define a set of local
;
; (let ((x 1) (y)) (setq y (+ x 1)) y)
-(def let (macro (let-param)
- ((lambda (vars exprs make-names make-exprs make-nils)
+(def let (macro (vars exprs)
+ ((lambda (make-names make-exprs make-nils)
(progn
;
)
)
)
- ;
+
; the set of expressions is
; the list of set expressions
; pre-pended to the
; expressions to evaluate
- ;
+
(setq make-exprs (lambda (vars exprs)
(progn
(cond (vars (cons
)
)
)
- (setq exprs (make-exprs vars exprs))
- ;
; the parameters to the lambda is a list
; of nils of the right length
- ;
+
(setq make-nils (lambda (vars)
(cond (vars (cons nil (make-nils (cdr vars))))
)
)
)
- ;
+ ; prepend the set operations
+ ; to the expressions
+
+ (setq exprs (make-exprs vars exprs))
+
; build the lambda.
- ;
+
(cons
(list
'lambda
)
)
)
- (car let-param)
- (cdr let-param)
()
()
()
)
)
- ;
- ; A slightly more convenient form
- ; for defining lambdas.
- ;
- ; (defun <name> (<params>) s-exprs)
- ;
+ ; run the let macro once to
+ ; evaluate all of the internal
+ ; macro calls
-(def defun (macro (defun-param)
- (let ((name (car defun-param))
- (args (cadr defun-param))
- (exprs (cdr (cdr defun-param))))
- (list
- def
- name
- (list
- 'lambda
- args
- (cond ((cdr exprs)
- (cons progn exprs))
- ((car exprs))
- )
- )
- )
- )
- )
- )
-
- ; simple math operators
- ;
- ; Do these last to run defun
- ; at least once so the let macro
- ; is resolved
+(let ((let-param 1)))
-(defun 1+ (x) (+ x 1))
-(defun 1- (x) (- x 1))