Utah Symbolic Computation Group May 1981
Operating Note No. 56
Portable Standard LISP Project List
by
M. L. Griss
University of Utah
Salt Lake City, UT 84112
Last Revision: 2 November 1981
ABSTRACT
This note lists "projects" that need to be done to complete or enhance the
developing Portable Standard LISP System. This includes additions or
modifications to the basic sources, applications of the system and tools, and
primitive facility development on newer target machines.
Work supported in part by the National Science Foundation under Grant No.
MCS80-07034.
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1. Introduction
This note is a guide to the current set of Projects that need to be
completed to enhance the developing versions of Portable Standard LISP (PSL);
the current versions are referred to as F-STDLSP and 20-STDLSP. For
convenience, F-STDLSP is referred to as FSL and 20-STDLSP is referred to as
20SL, and these are names used in files.
The projects divide into 3 major areas: Basic PSL development and
portability; PSL Applications and Tools; Support of PSL development on newer
machines.
2. Miscellaneous Small Enhancements and "Bugs"
a. We need a way of accessing LISP function with same name as SYSLISP
name [eg PLUS2] from SYSLISP, or causing better SYSLISP/LISP
renaming (cf SYSNAME); should use MODE-REDUCE (similar to LISPVAR
usage in SYSLISP) [Morrison?];
b. Document ERRORFORM!* and BREAKRETRY, make more ERRORs use
ERRORFORM!*; make ERRORFORM!* a fluid in appropriate places;
c. Have allocator functions call ERROR mechanism when no heap or GC
left, so that maybe unwind can release space; also maybe have
%RECLAIM have user hook per type so that user can monitor individual
type usage. How do we handle problem that ERROR uses some heap?;
d. Tighten BUILDING sequence, isolate a SYSLISP that can be run as a
stand-alone language, with a minimum number of support functions;
document CLEARLY, with a more formal specification of SYSLISP;
e. Isolate machine dependant code in earliest files, reorder rest of
functions with an eye to having just allocator, I/O and Fast-load in
base files, rest of LISP loaded onto this kernel by FASL [mostly
done, needs a FAP before further effort];
f. Add BIGNUM hooks, and rework BIGNUMs to use more effective storage
model; [Standard LISP source exists and has been tested
interpretively and compiled in the current STDLISP environment; low-
level hooks not yet in; probably should use WORD vectors in place of
lists]; add some of the BIGBIT operations that were used in Minor
work;
g. Permit Compiled and Interp NEXPRs. Consider LEXPRs. Perhaps a macro
package for N-ary functions. Perhaps examine an argument number
checking technique suggested by C. Griss: each call or definition of
a function with N-args, leans to use of a generated name, Foo-N;
this is really of the same level as treatment of FEXPR and MACRO
types in Standard Lisp: intead of FEXPRs, MACROs, and EXPRs, we have
FEXPRs, MACROs, EXPR0s, EXPR1s, EXPR2s...EXPRns;
h. Try to SYSLISP with primitives so that EVAL-APPLY-LAP support code
can be written in SYSLISP. Probably need LEXPR or stack local
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arrays. May involve "hard" compiler additons;
i. Optimize ARITHMETIC package, use SMACROs in place of PROCEDUREs to
get better speed on small INTs. Examine re-assigment of TAG bits to
optimize arithmetic dispatch;
j. Use macros to make certain calls of ARITH in system functions more
efficient; interface to Type'ing of MODE-RLISP.
3. I/O
a. Arbitray long input strings;
b. Bignum Parse/Print;
c. BINARY I/O for .FAP/.REL;
d. Packages (multi-symbol tables) interfaced as tree structured HASH
tables for Intern, invoked by Hook in I/O;
e. Implement Multi-Window Package (FRAMER), hooks to I/O;
f. Provide primitives for READ-TABLE switching;
g. Implement super PARENs (see NUREAD.RED by MLG, not in current
system);
3.1. Interrupts
Design better Interrupt Mechanism, decide how much control user should
have; perhaps only available to terminate various kinds of run-ways. Implement
a semi-portable interrupt machanism. We should probably look at what's
available on the most likely targets (Tops-20, Unix, VMS?, perhaps bare
hardware on some micros), and try to extract some common denominator (not
necessarily the LCD though -- if an OS doesn't offer anything reasonable, then
just bag interrupts for that implementation and be done with it).
The current implementation does not allow arbitrary lisp code to be run
from an interrupt, and then resumption, as a GC will lose anything pointed at
only from registers. There are two ways to rectify this "defect":
a. Go to a stack model for compiled code. I believe this would be a
mistake. One of the major virtues of the current model is the
excellent speed of compiled code. This is in large part due to the
register model used. For my applications, at least, I would prefer
the availability of raw speed, when desired, over arbitrary
interrupts. As noted below, I believe we still have sufficient
power in the interrupts available in the current model.
b. Partition the registers into tagged and untagged registers, and
modify the compiler so that any tagged object WHICH LIVES ONLY IN A
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REGISTER is in a tagged register. Note that the compiler may leave
tagged objects in an untagged register, which is OK so long as it
knows that another pointer to the same object lives on the stack or
in a value cell; however, the relocating GC can have problems, and
we need to go to a 2 stack model. A problem this may introduce in
the SysLisp version is parameter passing -- we may need two
different function linkage mechanisms -- one for tagged and one for
untagged objects. It may be possible to have the number of
registers of each type vary dynamically. Because of the tremendous
increase in complexity introduced by register partitioning, this
would be difficult, but probably should be faced.
I think we can live with a restricted interrupt mechanism. A fixed set of
conditions would exist, together with a collection of possible actions. The
user would be able to assign one of these (limited) actions to a condition.
The set of conditions would of necessity be somewhat machine dependent.
Hopefully a somewhat machine-independent subset could be made common to most
inplementations. This subset might include a number of terminal keys, various
"standard" error conditions such as I/O errors, and an alarm clock.
The set of actions would include:
a. Various carefully coded SysLisp routines intended for specific sorts
of conditions, such as an arithmetic overflow causing a bignum
package to be entered. These would be carefully coded so as to
allow resumption of the computation. This could also include things
such as a Tops-20 style ^T, or a quit back to the Exec.
b. Execute a given, arbitrary piece of Lisp code, and then throw to a
given tag. This could be used to generate an Error, enter a
breakloop to examine an infinite loop (and then return to top-
level), abort a computation and return to top-level (the code run on
top of the stack could set a hook to be run upon return to top-level
or whatever, as well), etc. This depends on the implementation of
Catch and Throw causing everything needed for the surrounding
context to be saved on the stack, and will require Throw to do some
of its work with interrupts disabled, before returning to CATCH.
Need to consider ARMING/DISARMING.
c. Set a flag for the interpreter, and then resume the computation.
Then, when the interpreter is next entered, an arbitrary piece of
Lisp code is run, and the interpreter can resume after this
"delayed" interrupt is handled. Should be able to do this kind of
delayed interrupt in general.
Note that the interrupt status must be altered upon entering the GC. We
cannot run Lisp code during a GC, so actions of the second sort, above, must be
deferred until after the GC. A number of those in class (1), above, may also
need to be deferred. Note that it is the actions which must change during a
GC, not the conditions.
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A possible collection of Lisp functions as user entry points to such a
mechanism are:
(InitializeInterrupts)
I'm not sure if this is needed at the user level, or if it
should just always happen as part of the Lisp startup
procedure.
(EnableInterrupts)
(DisableInterrupts)
(SetInterrupt <condition> <action>)
where <condition> is some appropriate keyword (an ID) such as
'ControlT, or 'StackOverflow, and <action> is either an
appropriate keyword such as 'QuitToExec, 'QuitToTopLevel, or
'PrintStatistics, or is a list such as '(InterpreterInterupt
(print "This is an interpreter interupt")) or '(ThrownInterupt
(print "Now we'll throw to ErrorSet") '!$Error!$). Note that
the function SetInterrupt is responsible for checking its
arguments.
(RemoveInterrupt <condition>)
4. Storage Management
a. Explore a variety of alternative Storage Management schemes: BIBOP,
COPYING;
b. Consider improved garbage collector/allocator, using AREAS, BIBOP or
some such; at least get SYSLISP items on non-traced stack (or stack
region); maybe have SYSLISP stack group; use bit-table rather than
RELOC fields, to permit extended addressing code to be run, use more
of word. Look at ELISP copying GC.
c. Consider collecting or relocating compiled code blocks, IDs and/or
GENSYMs;
5. New Machine Implementations
a. Bring up an extended addressing DEC-20 Standard LISP, using
essentially the same c-macros, and some additional kernel code
(developed at Rutgers for an extended addressing R/UCI LISP on the
DEC-20 by C. Hedrick).
b. Small Pointer DEC-20 with BIBOP and/or Bit-table for 18 bit
pointers;
c. Implement SYSLISP and PSL on PDP-11/45, as support for some of CAGD
tools - probably obselete ?;
d. Implement SYSLISP and PSL on VAX-750;
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e. Implement SYSLISP and PSL on M68000 [Apollo and Wicat];
f. Implement SYSLISP and PSL for Z80;
g. Re-implement FORTRAN version to check validity; move to CRAY; try
more "genuine" FORTRAN version; consider FORTRAN bootstrap; consider
PASLSP or KISLSP as bootstrap aid;
6. PASCAL like languages
ADA, C and PASCAL versions, continuing from TERAK experiments; do some
LILITH experiments [MODULA]. Major effort is current PASLSP on PERQ, Apollo and
Wicat. Later move PASLSP more into a SYSLISP to PASCAL.
a. Continue parameterizing (using # filter) 20, Terak, PERQ and Apollo
features; tighten source code, improve I/O; look at other PASCAL
LISPs;
b. Modularize so can be come "Library" for embedded systems (INS file
on Apollo, or MODULE for PERQ);
c. Extend GC for FIXNUM's, Strings and maybe vectors;
7. Support work on Apollo
7.1. Initial Experiments
a. Test LTNET.
b. Finish implementation of FTP (stream-IO back to 20, ratfor I/O on
20);
c. Should WICAT ftp to/from DOMAIN-net for shared printer?
d. Establish back-up command files, and save system on floppies.
e. Print and duplicate interesting HELP, DOC and INS files.
f. Test some simple assembly code;
g. Try BCPL and C cross assemblers;
7.2. Graphics
Idea is to explore Apollo graphics, provide library of Graphics and Window
routines for other utilities, eg VT52 emulator, Tek-like graphics terminal,
etc.
a. Borrow Summagraphics bit-pad from Brandt, and attach to one of SIO's
(via patch panel ?), and add to STROKES for test, or perhaps attach
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an SIO process to it, to send commands to DM input window (how?);
b. Perhaps adapt TERAK FONT and Graphics editors;
c. Test primitives (why didn't Scroll work);
d. try Bit-blt
e. try some of illegal "bits" (ie <-> MM, interlace, etc)
f. Faster Line drawing
g. RasterOp
h. Try Inverse Video Fonts
i. Reimplement own Window package.
j. Work on FONT editor: find font format's in one of INS files; Decode
STD and NONIE; Try create a font (see Terak Font Editor);
7.3. PSL work
a. Study ASM and architecture, develop notes on OS funnies (talk MDL,
Harvard, etc);
b. Modify PSL compiler (look at VAX work and Normans' 68000 stuff)
c. Try some codings and Boot it.
8. Impact of Other LISPs
a. Look at IMSSS additions (Utilities);
b. Study FRANZ-LISP, UCI-LISP and MACLISP for new features (also some
extensions and enhancements motivated by the work on InterLISP, NIL,
SPICE LISP and the LISP Machine);
c. Look at COMMON-LISP effort at CMU;
d. Develop macro package to permit FRANZ-LISP, MACLISP and InterLISP
code to be directly loaded. VERY important, see InterLISP utility;
e. Implement/examine CMU-Top-Level facilities (using MACLISP/FRANZLISP
sources);
f. Study VLISP Portability;
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9. Editor and Editor Interface
a. Implement EMID/EMODE multi-window, multi-buffer EMACS-like screen
editor [1]. This is planned to be the major interface to the PSL
system, and will have convenient commands (MODES) to edit LISP and
RLISP, examine documentation and convert LISP and RLISP to and from
other convenient forms. There are "autoparen" modes in which an
expression typed into a buffer automatically EVALs as soon as the
expression is complete. EMID has also been used to experimentally
develop a VLSI SLA editor (SLATE) [4] and will be used to do
algebraic expression "surgery". The new version of EMDOE should
concentrate on:
i. Good window/package interface;
ii. Interface to PSL (interactive editing of functions and
expressions);
iii. True "modes".
Implement EMACS fork call, using fixed page to pass text;
b. Implement the simple EDIT-like line-oriented editor based on
SOS/EDIT for editing RLISP/REDUCE and some LISP input; mostly for
people familiar with these editors.
c. Add a simple History mechanism [Cf CMU-LISP toplevel ];
d. Implement the InterLISP-like/UCI-Lisp like structure EDITOR (using
Nordtsrom source, UCI source, or IMSSS modified source);
10. Compiler and Loader
a. Need to implement 2 stacks for W-arith, etc.
b. Implement a FAP (fast loader); Currently, the c-macro loader (LAP),
and binary loader (FAP), are based on a variety of ad-hoc loaders
that have been written for the various machines and adapted for new
machines. Frick [5] has written a general purpose LAP and FAP in a
much more portable fashion (using a set of configuring parameters to
describe the kind of target machine), and it is planned to adopt
this as the basic LAP/FAP package when the STDLISP kernel is stable.
c. Make FAP and dynamic code space allocation part of kernel;
d. Implement DEC-20 .REL file loader;
e. Enhance resident compiler to accept SYSLISP;
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11. Language Extensions
a. Convert SYSLISP [3] from a BCPL-like language to a C-like language;
basic idea is to make use of some type information for more
effective compilation; Modes, Mode analysis and structure
definitions should be obtained from MODE system, but code-generation
for new SPECIFIC functions must be addressed;
b. Mode Analyzing RLISP/REDUCE [MODE-REDUCE] is an ALGOL-68 or PASCAL
like interface to Standard LISP, which provides an additional MODE
analysis pass after parsing, to rebind "generic" function names to
"specific" functions, based on the declared or analysed MODEs of
arguments. The system includes a variety of MODE generators (STRUCT,
UNION, etc) [10, 7, 9]. We plan to reimplement this system to use
SYSLISP/STDLISP more effectively. We will also make the MODE-
ANALYSIS phase part of SYSLISP, so that words, bytes, items etc. can
co-exist more naturally. Note that parsing from RLISP is into MODE-
STDLISP or MODE-SYSLISP [which now become same language];
c. Implement better RLISP parser and top loop "generating" functions;
d. Rename JUMPON to CASE or SWITCH; extend to include SELECTx
constructs;
e. Iteration and progs should be made more compatible. A single
iteration construct, equivalent to LISPM's DoNamed should be
implemented, and all other iteration and Prog contructs made macros
which map into it. I propose that Iterate is a better name than Do
or DoNamed. It may contain labels and Go's as a prog, and also
ReturnFrom's and a Next construct. A simple Return should simply
macro into a ReturnFrom the nearest Iterate, and similarly a next
which does not specify an Iterate tag. Go's should be allowed to
jump out to LEXICALLY surrounding Iterate's, but not across true
function calls. All this will be quite simple to implement so long
as all the nasty constructs such as WHILE and PROG and the like are
macros into a single construct such as Iterate. Prog's should
possibly also be extended to allow initial values to be specified as
for example (PROG (A B (N 0) (Flg T) X) ...) which would initialize
A, B, and X to nil, N to zero, and Flg to true. This is trivial to
do using Iterate as the target of the Prog macro. The map functions
would also be macros into an appropriate Iterate function. The FOR
macro (which has basically been implemented) would allow very
general sorts of loops and mapping functions, and would allow
returns and the like to pass through. Another excellent function to
have would be a ReturnTop or some such which returns from the
lexically outermost Iterate -- thus in general will return from the
function begin defined. Quite useful, I believe, though I don't
think it exists in any other lisps.
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12. Error Handler and Break Package
a. Modifications to Error handler(s), and BREAK/TRACE/BACKTRACE to
provide error "severity" level or classification so we can pick up
ALL error messages(templates), and BREAK can decide if it can start
a new (debugging) STDLSP or MUST strip stack.
b. Add more tools to BREAKLOOP, ie walk BSTACK to see OLD fluid values;
perhaps devise scheme to relate BSTACK sections with current Proc;
perhaps have PROCNAME pushed on BSTACK [only if has FLUIDS] (see the
DDT program by BENSON);
c. Design better Error Recovery mechanism, particular for error
correction and retry. An interface to EMODE would help, also an
interface to the "single" stepper (CMU-TOPLEVEL).
d. Examine the notion of Stack groups, and introduce an ERROR stack
group, since we run SYSLISP code using initial [STKLO,STKHI,ST], in
order to define a new [STKLO',STKHI',ST']; this stack group stuff
may help improve error handler.
e. Improve BREAK package (combine with EMBED, rename current BREAK to
BREAKLOOP, let BREAK be used to instrument a function: (BREAK FOO
condition action);
f. Add Error Severity classification;
g. Make some errors continuable: Undefined function, Unbound variable,
etc; Idea is perhaps to have CERROR(n,msg,errorform) for continuable
errors, FERROR(n,msg) for FATAL errors that cant use BREAK lOOP, and
ERROR(n,msg) for the most common case;
h. Implement the portable DEBUG package of functions for tracing,
breaking and embedding functions [11]. Facilities include the
(conditional) tracing of function calls and interpreted SETQs;
selective backtrace; embedding functions to selectively insert pre-
and post- actions, and conditions; primitive statistics gathering;
generation of simple stubs (print their name and argument, and read
a value to return); and, a PRINT for circular and re-entrant lists.
This will replace the simple TRACE package in the current kernel,
and interact more effectively with the BREAK package.
i. Timing Hooks;
j. Expand Macros in PUTDs (under flag control?);
13. Source Code Checking
a. IMSSS "syntax" checker;
b. Implement version of CREF for SYSLISP and STDLISP. CREF processes a
number of source files, cross-referencing the functions and Global
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variables used; gives an indication of where each function is
defined or redefined, its type (EXPR, FEXPR, etc), the functions and
variables it uses, various undefined functions and variables, and
other statistics that can be selected or deselected under flag
control [8].
14. Manual and Help Facility
a. Improve HELP, combine with other HELP mechanism. It will display
short text descriptions for major functions on request; by reading a
documentation data base, and should also display an activity based
HELP-TEXT (e.g. in response to ? at appropriate points).
b. The MANUAL is now fleshed out, but consists of a motley collection
of chapters and paragraphs. Both HELP and MANUAL require a
considerable amount of work in the conversion and writing of pieces
of text; we also need to co-ordinate with the SCRIBE sources for the
various documents already written. A model for a multi-chapter
scribe document has been tested, in which an index and table of
contents data-base are being built similarly to the usual AUX file;
at any time, an uptodate INDEX and TABLE of CONTENTS can be
produced;
c. A documentation mode of EMODE (ala INFO tree in EMACS).
15. Funarg, Closures and Stack Groups
Improve the binding scheme. Use a Baker-like scheme for fluid bindings,
and have locals in interpreted code.
To handle locals in interpreted code will require having those special
forms which know about locals to have special interpreter functions which are
passed an extra argument -- the lexical environment (probably as an a-list).
These will be essentially those f-exprs which are open-compiled: COND, AND,
OR, SETQ, PROG, various looping constructs (which I think should, together with
PROG, all be macros to a single DO-like special form), CATCH, THROW (these last
two are currently exprs, but I think should be made special), GO, RETURN. Note
that this would allow a somewhat more general use of things like return, which
I believe is all the the better. This is discussed a little bit more, below.
The fluid scheme I propose is essentially that of Baker, with rerooting
after EVERY binding and unbinding operation enforced. This allows us to still
always look for fluid values in the value cell. For further efficiency we can
still do our binding on the binding stack, which is now viewed as a binding
tree cache, so long as whenever we capture an environment (as with a Closure or
Catch) we write it out into the heap. This will substantially speed up binding
and unbinding in those cases where there is no intervening environment capture.
Also, use of STACK as cache to avoid much rebinding in list.
The capturing of an environment for a closure should be done not with
FUNCTION, which simply quotes its argument in such a manner that it is known to
be intended for execution, and should be compiled to code, but rather with a
third form of quote, probably called CLOSURE. There should also be a mechanism
�PSL Projects 12
for grabbing the current environment, without including a function to be run
therein, though of course (CLOSURE EVAL) can always be used to give this
effect.
Currently we are implementing a variant of Baker's [2] re-rooting scheme
to work well in the shallow binding environment; we expect that non-funarg
compiled code will run essentially as fast as in LISP 1.6. Context switches
will be more expensive.
We may also implement some form of Stack Group, as done by the LISP
machine group [6, 12], to provide faster large context switch.
Perhaps implement some form of LOCAL in interpreted code;
Consider ramifications of package system, funargs and stack groups as some
sort of static/dynamic environment methods;
16. Applications
a. Implement the REDUCE algebra system;
b. Get and Implement the VOCAL CAI language;
c. Bring up MINI and META, improve their use of I/O;
d. Implement Picture RLISP for TekTronix, HP, APOLLO, etc.
e. Implement extended SLATE on PSL and maybe combine with other VLSI
projects (ABLE->RLISP...).
f. FORTRAN (RATFOR?) to SYSLISP compilers for tools.
17. References
[1] Armantrout, R.; Benson, E.; Galway, W.; and Griss, M. L.
EMID: A Multi-Window Screen Editor Written in Standard LISP.
Utah Symbolic Computation Group Opnote No. 54, University of Utah,
Computer Science Department, Jan, 1981.
[2] Baker, H. G.
Shallow Binding in LISP 1.5.
CACM 21(7):565, July, 1978.
[3] Benson, E. and Griss, M. L.
SYSLISP: A portable LISP based systems implementation language.
Utah Symbolic Computation Group, Report UCP-81, University of Utah,
February, 1981.
[4] Carter, T.; Galway, W.; Goates, G.; Griss, M. L.; and Haslam, R.
SLATE: A Lisp Based EMACS Like Text Editor for SLA Design.
Utah Symbolic Computation Group Opnote No. 55, University of Utah,
Computer Science Department, Jan, 1981.
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[5] Frick, I. B.
A Portable Lap and Binary Loader.
Utah Symbolic Computation Group Operating Note Opnote No. 52, University
of Utah, November, 1979.
[6] Greenblatt, R.
The LISP Machine.
Technical Report ?, MIT, August, 1975.
[7] Griss, M. L.
The Definition and Use of Data-Structures in Reduce.
In Proceedings of SYMSAC 76, pages 53-59. SYMSAC, August, 1976.
[8] Griss, M. L.
RCREF: An Efficient REDUCE and LISP Cross-Reference Program.
Utah Symbolic Computation Group, Operating Note Opnote No. 30,
Univerisity of Utah, ??, 1977.
[9] Griss, Martin L.; Hearn, A. C; and Maguire, G. Q., Jr.
Using The MODE Analyzing version of REDUCE.
Utah Symbolic Computation Group Opnote No. 48, Dept of CS, U of U, Jun,
1980.
[10] Hearn, A. C.
A Mode Analyzing Algebraic Manipulation Program.
In Proceedings of ACM 74, pages 722-724. ACM, New York, New York, 1974.
[11] Norman, A.C. and Morrison, D. F.
The REDUCE Debugging Package.
Utah Symbolic Computation Group, Operating Note Opnote No. 49, Dept of
CS, U of U, Feb, 1981.
[12] Weinreb, D. and Moon, D.
LISP Machine Manual.
Manual , M. I. T., January, 1979.
second preliminary version.
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Table of Contents
1. Introduction 2
2. Miscellaneous Small Enhancements and "Bugs" 2
3. I/O 3
3.1. Interrupts 3
4. Storage Management 5
5. New Machine Implementations 5
6. PASCAL like languages 6
7. Support work on Apollo 6
7.1. Initial Experiments 6
7.2. Graphics 6
7.3. PSL work 7
8. Impact of Other LISPs 7
9. Editor and Editor Interface 8
10. Compiler and Loader 8
11. Language Extensions 9
12. Error Handler and Break Package 10
13. Source Code Checking 10
14. Manual and Help Facility 11
15. Funarg, Closures and Stack Groups 11
16. Applications 12
17. References 12