PSL Manual 7 February 1983 SYSLISP
section 20.0 page 20.1
CHAPTER 20
CHAPTER 20
CHAPTER 20
SYSLISP
SYSLISP
SYSLISP
20.1. Introduction to the SYSLISP level of PSL. . . . . . 20.1
20.2. The Relationship of SYSLISP to RLISP . . . . . . . 20.2
20.2.1. SYSLISP Declarations . . . . . . . . . . 20.2
20.2.2. SYSLISP Mode Analysis. . . . . . . . . . 20.3
20.2.3. Defining Special Functions for Mode Analysis . . 20.4
20.2.4. Modified FOR Loop . . . . . . . . . . . 20.4
20.2.5. Char and IDLOC Macros. . . . . . . . . . 20.5
20.2.6. The Case Statement. . . . . . . . . . . 20.6
20.2.7. Memory Access and Address Operations. . . . . 20.7
20.2.8. Bit-Field Operation . . . . . . . . . . 20.8
20.3. Using SYSLISP. . . . . . . . . . . . . . . 20.9
20.3.1. To Compile SYSLISP Code . . . . . . . . . 20.9
20.4. SYSLISP Functions . . . . . . . . . . . . . 20.10
20.4.1. W-Arrays . . . . . . . . . . . . . . 20.11
20.5. Remaining SYSLISP Issues . . . . . . . . . . . 20.12
20.5.1. Stand Alone SYSLISP Programs . . . . . . . 20.12
20.5.2. Need for Two Stacks . . . . . . . . . . 20.12
20.5.3. New Mode System. . . . . . . . . . . . 20.13
20.5.4. Extend CREF for SYSLISP . . . . . . . . . 20.13
This chapter is very out of date and will be replaced as soon as
possible.
20.1. Introduction to the SYSLISP level of PSL
20.1. Introduction to the SYSLISP level of PSL
20.1. Introduction to the SYSLISP level of PSL
SYSLISP [Benson 81] is a BCPL-like language, couched in LISP form,
providing operations on machine words, machine bytes and LISP ITEMs (tagged
objects, packed into one or more words). We actually think of SYSLISP as a
lower level of PSL, dealing with words, bytes, bit-fields, machine
operations, and compile-time storage allocation, enabling us to write
essentially all of the kernel in PSL.
The control structures and definition language are those of LISP, but the
Plus2 Times2 WPlus2 WTimes2
Plus2 Times2 WPlus2 WTimes2
familiar Plus2, Times2, etc. are mapped to word operations WPlus2, WTimes2,
etc. SYSLISP handles static allocation of SYSLISP variables and arrays and
initial LISP symbols, permitting the easy definition of higher level
Standard LISP functions and storage areas. SYSLISP provides convenient
______
compile-time constants for handling strings, LISP symbols, etc. The
SYSLISP compiler is based on the PORTABLE STANDARD LISP Compiler, with
extensions to handle word level objects and efficient, open-coded,
word-level operations. The SYSLISP mode of the compiler does efficient
compile-time folding of constants and more comprehensive register
allocation than in the distributed version of the PLC. Currently, SYSLISP
handles bytes through the explicit packing and unpacking operations
�SYSLISP 7 February 1983 PSL Manual
page 20.2 section 20.1
GetByte
GetByte
GetByte(word-address,byte-number) /
PutByte
PutByte
PutByte(word-address,byte-number,byte-value) without the notion of byte-
pointer; it is planned to extend SYSLISP to a C-like language by adding the
appropriate declarations and analysis of word/byte/structure operations.
SYSLISP is a collection of functions and their corresponding data types
which are used to implement low level primitives in PSL, such as storage
allocation, garbage collection and input and output. The basic data object
____
in SYSLISP is the "word", a unit of storage large enough to contain a LISP
____ ____ ____
item. On the PDP-10, a SYSLISP word is just a 36-bit PDP-10 word. On the
____
VAX and most other byte addressed machines, a word is 4 bytes, or 32 bits.
Conceptually, SYSLISP functions manipulate the actual bit patterns found in
words, unlike normal LISP functions which manipulate higher-level objects,
____ ______ _____ ______
such as pairs, vectors, and floats or arbitrary-precision numbers.
Arithmetic in SYSLISP is comparable to the corresponding operations in
FORTRAN or PASCAL. In fact, SYSLISP is most closely modeled after BCPL, in
that operations are essentially "typeless".
20.2. The Relationship of SYSLISP to RLISP
20.2. The Relationship of SYSLISP to RLISP
20.2. The Relationship of SYSLISP to RLISP
______
______
______
smacro
smacro
RLISP was extended with a CASE statement, SYSLISP declarations, smacros
_____
_____
_____
macro
macro
and macros to provide convenient infix syntax (+, *, / etc.) for calling
the SYSLISP primitives. Even though SYSLISP is semantically somewhat
different from LISP (RLISP), we have tried to keep the syntax as similar as
possible so that SYSLISP code is "familiar" to RLISP users, and easy to
use. RLISP functions can be easily converted and interfaced to functions
at the SYSLISP level, gaining considerable efficiency by declaring and
directly using words and bytes instead of tagged LISP objects.
20.2.1. SYSLISP Declarations
20.2.1. SYSLISP Declarations
20.2.1. SYSLISP Declarations
SYSLISP variables are either GLOBAL, memory locations (allocated by the
compiler), or local stack locations. Locals are declared by SCALAR, as
usual. Globals come in the following flavors:
WCONST id = wconstexp {,id = wconstexp} ;
Wconstexp is an expression involving constants and wconsts.
WVAR wvardecl {, wvardecl} ;
wvardecl ::= id | id = wconstexp
WARRAY warraydecl {, warraydecl} ;
warraydecl ::= id[wconstexp] | id[] = [ wconstexp {,wconstexp} ]
| id[] = string
�PSL Manual 7 February 1983 SYSLISP
section 20.2 page 20.3
WSTRING warraydecl {, warraydecl} ;
Each of these declarations can also be prefixed with the keywords:
INTERNAL or EXTERNAL.
If nothing appears, then a DEFAULT is used.
(Notice there are no metasyntactic square brackets here,
only curly brackets.)
For example, the following GLOBAL-DATA is used in PSL:
on SysLisp;
exported WConst MaxSymbols = 8000,
MaxConstants = 500,
HeapSize = 100000;
external WArray SymNam, SymVal, SymFnc, SymPrp, ConstantVector;
external WVar NextSymbol, NextConstant;
exported WConst MaxRealRegs = 5,
MaxArgs = 15;
external WArray ArgumentBlock;
off SysLisp;
END;
20.2.2. SYSLISP Mode Analysis
20.2.2. SYSLISP Mode Analysis
20.2.2. SYSLISP Mode Analysis
____
In SYSLISP mode, the basic operators +, *, -, /, etc., are bound to word
WPlus2 WTimes2 WMinus
WPlus2 WTimes2 WMinus
operators (WPlus2, WTimes2, WMinus, etc.), which compile OPEN as
____
conventional machine operations on machine words. Thus most SYSLISP
expressions, loops, etc. look exactly like their RLISP equivalents.
20.2.3. Defining Special Functions for Mode Analysis
20.2.3. Defining Special Functions for Mode Analysis
20.2.3. Defining Special Functions for Mode Analysis
To have the Mode analyzer (currently a REFORM function) replace LISP
function names by SYSLISP ones, do:
PUT('LispName,'SYSNAME,'SysLispName);
�SYSLISP 7 February 1983 PSL Manual
page 20.4 section 20.2
The Following have been done:
DefList('((Plus WPlus2)
(Plus2 WPlus2)
(Minus WMinus)
(Difference WDifference)
(Times WTimes2)
(Times2 WTimes2)
(Quotient WQuotient)
(Remainder WRemainder)
(Mod WRemainder)
(Land WAnd)
(Lor WOr)
(Lxor WXor)
(Lnot WNot)
(LShift WShift)
(LSH WShift)), 'SysName);
DefList('((Neq WNeq)
(Equal WEq)
(Eqn WEq)
(Eq WEq)
(Greaterp WGreaterp)
(Lessp WLessp)
(Geq WGeq)
(Leq WLeq)
(Getv WGetv)
(Indx WGetv)
(Putv WPutv)
(SetIndx WPutv)), 'SysName);
20.2.4. Modified FOR Loop
20.2.4. Modified FOR Loop
20.2.4. Modified FOR Loop
Wxxxx
Wxxxx
The FOR loop is modified in SYSLISP mode to use the Wxxxx functions to do
loop incrementation and testing.
[??? Should pick up via SysReform ???]
[??? Should pick up via SysReform ???]
[??? Should pick up via SysReform ???]
20.2.5. Char and IDLOC Macros
20.2.5. Char and IDLOC Macros
20.2.5. Char and IDLOC Macros
____
In SYSLISP mode, '<id> refers to the tagged item, just as in LISP mode,
IdLoc LispVar
IdLoc __ LispVar
IdLoc <id> refers to the id space offset of the <id>, and LispVar <id>
____
refers to the GLOBAL value cell of a GLOBAL or FLUID variable. Note:
LispVar
LispVar
LispVar can be used on the left hand side of an argument sentence. For
__
example, to store a NIL in the value cell of id FOO, we do any one of the
following.
�PSL Manual 7 February 1983 SYSLISP
section 20.2 page 20.5
SYMVAL IDLOC FOO := 'NIL;
LISPVAR FOO := MKITEM(ID,IDLOC NIL);
Char
Char _ __ _______ _____
(Char U:id): integer macro
Char
Char
The Char macro returns the ASCII code corresponding to its single
character-id argument. CHAR also can handle alias's for certain special
characters, remove QUOTE marks that may be needed to pass special
characters through the parser, and can accept a prefixes to compute LOWER
case, <Ctrl> characters, and <Meta> characters. For example:
Little_a:= Char LOWER A; % In case we think RAISE will occur
Little_a:= Char '!a; % !a should not be raised
Meta_X := Char META X;
Weird := Char META Lower X;
Dinger := Char <Ctrl-G>;
Dinger := Char BELL;
PUT
PUT
The following Aliases are defined by PUTing the association under the
indicator 'CharConst:
DefList('((NULL 8#0)
(BELL 8#7)
(BACKSPACE 8#10)
(TAB 8#11)
(LF 8#12)
(EOL 8#12)
(FF 8#14)
(CR 8#15)
(EOF 26)
(ESC 27)
(ESCAPE 27)
(BLANK 32)
(RUB 8#177)
(RUBOUT 8#177)
(DEL 8#177)
(DELETE 8#177)), 'CharConst);
20.2.6. The Case Statement
20.2.6. The Case Statement
20.2.6. The Case Statement
RLISP in SYSLISP mode provides a Numeric case statement, that is
implemented quite efficiently; some effort is made to examine special cases
(compact vs. non compact sets of cases, short vs. long sets of cases,
etc.).
[??? Note, CASE can also be used from LISP mode, provided tags are
[??? Note, CASE can also be used from LISP mode, provided tags are
[??? Note, CASE can also be used from LISP mode, provided tags are
numeric. There is also an FEXPR, CASE ???]
numeric. There is also an FEXPR, CASE ???]
numeric. There is also an FEXPR, CASE ???]
The syntax is:
�SYSLISP 7 February 1983 PSL Manual
page 20.6 section 20.2
Case-Statement ::= CASE expr OF case-list END
Case-list ::= Case-expr [; Case-list ]
Case-expr ::= Tag-expr : expr
tag-expr ::= DEFAULT | OTHERWISE |
tag | tag, tag ... tag |
tag TO tag
Tag ::= Integer | Wconst-Integer
% This is a piece of code from the Token Scanner,
% in file "PI:token-Scanner.red"
.....
case ChTokenType of
0 to 9: % digit
<< TokSign := 1;
goto InsideNumber >>;
10: % Start of ID
<< if null LispVar !*Raise then
goto InsideID
else
<< RaiseLastChar();
goto InsideRaisedID >> >>;
11: % Delimiter, but not beginning of diphthong
<< LispVar TokType!* := '3;
return MkID TokCh >>;
12: % Start of comment
goto InsideComment;
13: % Diphthong start-Lisp function uses P-list of starting char
return ScanPossibleDipthong(TokChannel, MkID TokCh);
14: % ID escape character
<< if null LispVar !*Raise then
goto GotEscape
else goto GotEscapeInRaisedID >>;
15: % string quote
<< BackupBuf();
goto InsideString >>;
16: % Package indicator -
% at start of token means use global package
<< ResetBuf();
ChangedPackages := 1;
Package 'Global;
if null LispVar !*Raise then
goto GotPackageMustGetID
else goto GotPackageMustGetIDRaised >>;
17: % Ignore - can't ever happen
ScannerError("Internal error - consult a wizard");
18: % Minus sign
<< TokSign := -1;
�PSL Manual 7 February 1983 SYSLISP
section 20.2 page 20.7
goto GotSign >>;
19: % Plus sign
<< TokSign := 1;
goto GotSign >>;
20: % decimal point
<< ResetBuf();
ReadInBuf();
if ChTokenType >= 10 then
<< UnReadLastChar();
return ScanPossibleDipthong(TokChannel, '!.) >>
else
<< TokSign := 1;
TokFloatFractionLength := 1;
goto InsideFloatFraction >> >>;
default:
return ScannerError("Unknown token type")
end;
.....
20.2.7. Memory Access and Address Operations
20.2.7. Memory Access and Address Operations
20.2.7. Memory Access and Address Operations
The operators @ and & (corresponding to GetMem and Loc) may be used to do
direct memory operations, similar to * and & in C.
@ may also be used on the LHS of an assignment. Example:
WARRAY FOO[10];
WVAR FEE=&FOO[0];
...
@(fee+2) := @(fee+4) + & foo(5);
...
20.2.8. Bit-Field Operation
20.2.8. Bit-Field Operation
20.2.8. Bit-Field Operation
The Field and PutField operations are used for accessing fields smaller
than whole words:
PUTFIELD(LOC, BITOFFSET, BITLENGTH, VALUE);
and
GETFIELD(LOC,BITOFFSET, BITLENGTH);
Special cases such as bytes, halfwords, single bits are optimized if
possible.
For example, the following definitions on the DEC-20 are used to define
�SYSLISP 7 February 1983 PSL Manual
page 20.8 section 20.2
the fields of an item (in file p20c:data-machine.red):
% Divide up the 36 bit DEC-20 word:
WConst TagStartingBit = 0,
TagBitLength = 18,
StrictTagStartingBit = 9,
StrictTagBitLength = 9,
InfStartingBit = 18,
InfBitLength = 18,
GCStartingBit = 0,
GCBitLength = 9;
% Access to tag (type indicator) of Lisp item in ordinary code
syslsp macro procedure Tag U;
list('Field, cadr U, '(wconst TagStartingBit), '(wconst TagBitLe
syslsp macro procedure PutTag U;
list('PutField, cadr U, '(wconst TagStartingBit),
'(wconst TagBitLength), caddr U);
% Access to tag of Lisp item in garbage collector,
% if GC bits may be in use
syslsp macro procedure StrictTag U;
list('Field, cadr U, '(wconst StrictTagStartingBit),
'(wconst StrictTagBitLength));
syslsp macro procedure PutStrictTag U;
list('PutField,
cadr U, '(wconst StrictTagStartingBit),
'(wconst StrictTagBitLength), caddr U);
% Access to info field of item (pointer or immediate operand)
syslsp macro procedure Inf U;
list('Field, cadr U, '(wconst InfStartingBit), '(wconst InfBitLe
syslsp macro procedure PutInf U;
list('PutField, cadr U, '(wconst InfStartingBit),
'(wconst InfBitLength), caddr U);
�PSL Manual 7 February 1983 SYSLISP
section 20.3 page 20.9
20.3. Using SYSLISP
20.3. Using SYSLISP
20.3. Using SYSLISP
___________
Restriction: SYSLISP code is currently ONLY compiled, since it is
converted into machine level operations, most of which are dangerous or
tricky to use in an interpreted environment.
Note: In SYSLISP mode, we currently execute some commands in the above
PARSE/EVAL/PRINT mode, either to load files or select options, but most
SYSLISP code is compiled to a file, rather than being immediately
interpreted or compiled in-core.
20.3.1. To Compile SYSLISP Code
20.3.1. To Compile SYSLISP Code
20.3.1. To Compile SYSLISP Code
Use PSL:RLISP, which usually has the Compiler, with SYSLISP extensions,
loaded. Alternatively, one may use <psl>syscmp.exe. This is a version of
RLISP built upon <PSL>psl.exe with the SYSLISP compiler and data-machine
macros loaded.
% Turn on SYSLISP mode:
ON SYSLISP; % This is causes the "mode-analysis" to be done
% Converting some LISP names to SYSLISP names.
% Use SYSLSP as the procedure type.
Example:
% Small file to access BPS origin and end.
% Starts in LISP mode
Fluid '(NextBP0 LastBP0);
NextBP0:=NIL;
LastBP0:=NIL;
On SYSLISP,COMP; % Switch to SYSLISP mode
syslsp procedure BPSize();
Begin scalar N1,L1;
If Null LispVar NextBP0 then LispVar NextBP0:=GtBPS 0;
If Null LispVar LastBP0 then LispVar LastBP0:=GtWarray 0;
N1 :=GtBPS(0);
L1:= GtWarray(0);
PrintF('" NextBPS=8#%o, used %d, LastBPS=8#%o, used %d%n",
N1, N1-LispVar(NextBP0), L1,LispVar(LastBP0)-L1)
LispVar NextBP0:=N1;
LispVar LastBP0:=L1;
End;
BPSize(); % Call the function
�SYSLISP 7 February 1983 PSL Manual
page 20.10 section 20.4
20.4. SYSLISP Functions
20.4. SYSLISP Functions
20.4. SYSLISP Functions
[??? What about overflow in Syslisp arithmetic? ???]
[??? What about overflow in Syslisp arithmetic? ???]
[??? What about overflow in Syslisp arithmetic? ???]
WPlus2
WPlus2 _ ____ _ ____ ____ ____ ________ ____
(WPlus2 U:word, V:word): word open-compiled, expr
WDifference
WDifference _ ____ _ ____ ____ ____ ________ ____
(WDifference U:word, V:word): word open-compiled, expr
WTimes2
WTimes2 _ ____ _ ____ ____ ____ ________ ____
(WTimes2 U:word, V:word): word open-compiled, expr
WQuotient
WQuotient _ ____ _ ____ ____ ____ ________ ____
(WQuotient U:word, V:word): word open-compiled, expr
WRemainder
WRemainder _ ____ _ ____ ____ ____ ________ ____
(WRemainder U:word, V:word): word open-compiled, expr
WShift
WShift _ ____ _ ____ ____ ____ ________ ____
(WShift U:word, V:word): word open-compiled, expr
WAnd
WAnd _ ____ _ ____ ____ ____ ________ ____
(WAnd U:word, V:word): word open-compiled, expr
WOr
WOr _ ____ _ ____ ____ ____ ________ ____
(WOr U:word, V:word): word open-compiled, expr
WXor
WXor _ ____ _ ____ ____ ____ ________ ____
(WXor U:word, V:word): word open-compiled, expr
WNot
WNot _ ____ ____ ____ ________ ____
(WNot U:word): word open-compiled, expr
WEQ
WEQ _ ____ _ ____ _______ ____ ________ ____
(WEQ U:word, V:word): boolean open-compiled, expr
WNEQ
WNEQ _ ____ _ ____ _______ ____ ________ ____
(WNEQ U:word, V:word): boolean open-compiled, expr
WGreaterP
WGreaterP _ ____ _ ____ _______ ____ ________ ____
(WGreaterP U:word, V:word): boolean open-compiled, expr
WLessP
WLessP _ ____ _ ____ _______ ____ ________ ____
(WLessP U:word, V:word): boolean open-compiled, expr
WGEQ
WGEQ _ ____ _ ____ _______ ____ ________ ____
(WGEQ U:word, V:word): boolean open-compiled, expr
�PSL Manual 7 February 1983 SYSLISP
section 20.4 page 20.11
WLEQ
WLEQ _ ____ _ ____ _______ ____ ________ ____
(WLEQ U:word, V:word): boolean open-compiled, expr
WGetV
WGetV _ ____ _ ____ ____ ____ ________ _____
(WGetV U:word, V:word): word open-compiled, macro
WPutV
WPutV _ ____ _ ____ _ ____ ____ ____ ________ _____
(WPutV U:word, V:word, W:word): word open-compiled, macro
Byte
Byte _ ____ _ ____ ____ ____ ________ ____
(Byte U:word, V:word): word open-compiled, expr
PutByte
PutByte _ ____ _ ____ _ ____ ____ ____ ________ ____
(PutByte U:word, V:word, W:word): word open-compiled, expr
20.4.1. W-Arrays
20.4.1. W-Arrays
20.4.1. W-Arrays
CopyWArray
CopyWArray ___ _ ______ ___ _ ______ _____ ___ ___ _ ______ ____
(CopyWArray NEW:w-vector, OLD:w-vector, UPLIM:any): NEW:w-vector expr
_____
Copy UPLIM + 1 words.
CopyWRDSToFrom
CopyWRDSToFrom ___ _ ______ ___ ___ ___ ____
(CopyWRDSToFrom NEW:w-vector, OLD:any): any expr
CopyWArray
CopyWArray
Like CopyWArray in heap.
CopyWRDS
CopyWRDS _ ___ ___ ____
(CopyWRDS S:any): any expr
Allocate new WRDS array in heap.
20.5. Remaining SYSLISP Issues
20.5. Remaining SYSLISP Issues
20.5. Remaining SYSLISP Issues
The system should be made less dependent on the assemblers, compilers and
loaders of the particular machine it is implemented on. One way to do this
is to bring up a very small kernel including a fast loader to load in the
rest.
20.5.1. Stand Alone SYSLISP Programs
20.5.1. Stand Alone SYSLISP Programs
20.5.1. Stand Alone SYSLISP Programs
In principle it works, but we need to clearly define a small set of
support functions. Also, need to implement EXTERNAL properly, so that a
normal LINKING loader can be used. In PSL, we currently produce a single
kernel module, with resident LAP (or later FAP), and it serves as dynamic
linking loader for SYSLISP (ala MAIN SAIL).
�SYSLISP 7 February 1983 PSL Manual
page 20.12 section 20.5
20.5.2. Need for Two Stacks
20.5.2. Need for Two Stacks
20.5.2. Need for Two Stacks
We must distinguish between true LISP items and untagged SYSLISP items on
the stack for the garbage collector to work properly. Two of the options
for this are
1. Put a mark on the stack indicating a region containing untagged items.
2. Use a separate stack for untagged items.
Either of these involves a change in the compiler, since it currently
only allocates one frame for temporaries on the stack and does not
distinguish where they get put.
The garbage collector should probably be recoded more modularly and at a
higher level, short of redesigning the entire storage management scheme.
This in itself would probably require the existence of a separate stack
which is not traced through for return addresses and SYSLISP temporaries.
20.5.3. New Mode System
20.5.3. New Mode System
20.5.3. New Mode System
A better scheme for intermixing SYSLISP and LISP within a package is
needed. Mode Reduce will probably take care of this.
20.5.4. Extend CREF for SYSLISP
20.5.4. Extend CREF for SYSLISP
20.5.4. Extend CREF for SYSLISP
The usual range of LISP tools should be available, such as profiling, a
break package, tracing, etc.