File psl-1983/3-1/doc/psl-vm.doc artifact 7569b87d41 on branch master


                NOTES ON THE PSL VIRTUAL MACHINE
                           Cris Perdue
                             3-8-83
              -------------------------------------

NOTES ON THE SYSLISP DATATYPES
------------------------------

Most of the PSL low-level operators deal with values that are of
a standard size for a given machine.  Tagged LISP "items" are of
this size, as are "machine-integers" and "machine-pointers" (see
below for details on these datatypes).

A machine-integer is a value to which operations such as WPLUS2,
WOR and WSHIFT apply.  These are listed in the documentation for
SYSLISP.  The arithmetic operators are all signed arithmetic.

A machine-pointer is a machine-integer which may be an argument
to byte, memory, putmem, wgetv, etc..  It is legitimate to use
address arithmetic, but the difference between the addresses of
two adjacent items may be an integer greater than one.  The
difference between the addresses of two adjacent items (words) is
the value of the WCONST AddressingUnitsPerItem.

PROBLEMS WITH THE USE OF MACHINE-INTEGERS AND MACHINE-POINTERS

In the current implementation of PSL a machine-integer serves as
the representation for every LISP integer of less than a certain
size.  Within this range of values, no conversion is required and
machine integers can neither confuse the garbage collector nor be
trashed by the garbage collector.

If a machine integer outside this range resides where the garbage
collector expects an item, for example in the stack, it is liable
to be taken as a tagged pointer.  If it appears to have a legal
tag, the garbage collector is likely to try to examine the word
pointed to and this may cause an odd address error or memory bus
error.  Also the integer may well be "relocated", i.e. altered to
"point" to the new location of the data after the garbage
collection -- the garbage collectors move heap objects.  Even if
none of these catastrophic events occurs, the garbage collector
may be prevented from collecting some garbage because the integer
gave the appearance of pointing to it.

Machine-pointers suffer from some similar problems.  If a garbage
collection should occur during the active lifetime of a
machine-pointer that points into the heap, that pointer will
cease to point to the intended object.

A NOTE ON PREDICATES

All of the predicates described in this document return LISP
boolean values, i.e. NIL or not-NIL.  When used to affect flow of
control, they compile just as the corresponding tests would in C
or PASCAL, without reference to any LISPy values.


ARITHMETIC AND LOGICAL OPERATIONS
---------------------------------

WPLUS2, WDIFFERENCE, WTIMES2, WQUOTIENT, WREMAINDER

Signed arithmetic with word-sized arguments and result.

(WSHIFT value amount)

Logical shift left or right.  Positive shift amounts mean
shifting to the left.  The absolute value of the shift amount
should be less than the number of bits per item.

WMINUS

Unary negation.

WAND, WOR, WXOR

Binary bitwise logical operators.

WNOT

Unary logical complement (logical negation).

WEQ, WNEQ

Equality of item-sized values.  Serves for both logical and
arithmetic equality.  The result is a LISP boolean value (NIL or
not NIL), which is not necessarily materialized.

WGREATERP, WLESSP, WGEQ, WLEQ

Signed arithmetic booleans.  The result is a LISP boolean value
(NIL or not NIL) which is not necessarily materialized.

(FIELD value startingbit length), (SIGNEDFIELD value startingbit length)

These operators extract fields from item-sized quantities.  The
extracted field is right-justified.  FIELD pads the result with
zeroes, and SIGNEDFIELD pads the result with ones if the most
significant bit of the field is a one.  Bits are numbered with
the most significant bit as bit zero.  The startingbit and length
arguments must be compile-time constants.


MEMORY-ORIENTED OPERATIONS
--------------------------

(GETMEM pointer)

Given a machine pointer, returns the word pointed to.

(PUTMEM pointer value)

Given a machine pointer and a word-sized value, stores the value
into the word pointed to.

(PUTFIELD pointer startingbit length value)

Given a machine pointer, compile-time constants startingbit and
length, and a word-sized value, the low-order bits of the value
are stored into the specified field of the word referred to by
pointer.  Is a value returned?

(WGETV pointer offset), (WPUTV pointer offset value)

These provide access to words at addresses that are offset from
some address.  (WGETV pointer 0) is equivalent to (GETMEM
pointer).  Does WPUTV return a value?

(BYTE pointer index), (PUTBYTE pointer index value)

These provide access to vectors of byte-sized quantities.  The
pointer is a machine-pointer to the first word in which the bytes
may be stored.  The index must be zero or greater.  BYTE extracts
a byte and pads with zeroes.  PUTBYTE stores the low-order bits
of the value into a byte in memory.  Does PUTBYTE return a value?

(HALFWORD pointer index), (PUTHALFWORD pointer index value)

These provide access to vectors of quantities packable 2 per
word.  They are analagous to BYTE and PUTBYTE, and the value of
HALFWORD is zero-padded.

LOC

Use with variable names including WVARs and WARRAYs?  Also with
WGETV expressions?

WCONST

WCONSTs can be used in any LISP code by writing a compile-time
constant expression: (WCONST <expression>).  The expression may
use WCONSTs by name.  If WDECLARE is loaded (as in SYSLISP),
named WCONSTs (and only WCONSTs) may be declared using the
WDECLARE function.

CROSS-COMPILER ONLY -- WVAR, WARRAY, WSTRING

For WVARs, declare them first then use by name.  <<So why say
LISPVAR at all in SysLisp?>>

Use WCONSTs as (WCONST expression) or alternatively (I think)
declare first and use by name.

Use of WARRAY or WSTRING by name means address of zeroth element,
rather like a WCONST.(?)

DECLARING WVARS, WARRAYS, WSTRINGS, AND WCONSTS

(WDeclare scope type (name bound init) (name [bound init]) . . . )

Scope is EXPORTED, EXTERNAL, or DEFAULT.  (Meaning of DEFAULT?)
Type is WVAR, WARRAY, WSTRING, or WCONST.
Bound and Init are optional and mutually exclusive.  Bound can
  only apply to a WARRAY or WSTRING, and gives the upper bound of
  the array or string.  Init is a compile-time constant
  expression in the case of a WVAR, or a list (of constant
  expressions?) in the case of a WARRAY, or a string in the case
  of a WSTRING.  I think the list form is legal for a string, in
  which case the members are taken as ASCII codes for characters.
  (This information is not guaranteed!)


CONVERSION BETWEEN LISP- AND MACHINE-VALUES
-------------------------------------------

INUMs need no conversion.  For machine-integers in general, the
functions SYS2INT and INT2SYS convert to and from LISP numeric
values.


ON "ITEMS"
----------

All PSL "pointers" are "items", also known as "tagged items".  An
item consists of a tag part and an information part.  In current
implementations the parts occupy fixed fields of a fixed-size
quantity, but this has not been so in every implementation.

In what follows note that BYTES are only partially implemented
and that from the user's point of view, HALFWORDS are
an experiment.  Use them with the understanding that a redesign
of the system datatypes might cause them to be eliminated.


TAGGED ITEM CONSTRUCTORS
------------------------

(MkBTR MkID MkFIXN MkFLTN MkBIGN MkPAIR
       MkVEC MkEVECT MkWRDS MkSTR MkBYTES
       MkHalfWords MkCODE)

Given a machine-integer data part, these return a tagged item of
the type suggested by the name of the constructor, with data part
same as the argument.


TAGGED ITEM COMPONENTS
----------------------

(IDInf StrInf VecInf EvecInf PairInf WrdInf HalfWordInf CodeInf
       FixInf FltInf BigInf)


(PutIDInf PutStrInf PutVecInf PutPairInf PutWrdInf
	  PutHalfWordInf PutEvecInf
	  PutFixInf PutFltInf PutBigInf)

Given a machine pointer to an item, these fetch or store the data
part of the item pointed to.  The value returned by the accessors
is in machine format.

Note:  ByteInf and PutByteInf are missing.

(Tag U)

Gets the tag part of an item.  Clear enough what this does now,
but what are its specifications?


PREDICATES ON TAGS
------------------

Each of these predicates takes a LISP item as its argument and
returns a LISP boolean if used for its value.

NOTE: By clever ordering of the values of the type tags, ALL of
these tests are comparable in speed.  In fact, on the 9836 they
may soon all be just about the same speed, so don't hesitate to
use the most appropriate one!

PAIRP, STRINGP, VECTORP, CODEP, IDP, BYTESP, WRDSP, HALFWORDSP

These are all independent predicates on the type of an item.

FIXNP, FLOATP, BIGP

These are checks for specific sorts of numbers.  Testing for
FLOATP is probably the most legitimate for use in user code,
though see the function FLOAT also.

INTP, FIXP, NUMBERP

These are related type tests.  FIXP and NUMBERP are quite
legitimate to use in general user-level programs.  INTP tests
whether a number is in the "INUM range", that is, is represented
directly by an item rather than using space in the heap.  If a
number is INTP, at present it has the same representation as a
machine-integer of the same value.

POSINTP, NEGINTP

POSINTP checks for a positive INUM (or zero), and NEGINTP checks
for a negative INUM.  These happen at present to be separate type
tags.

There are actually even more obscure tags, but these are of very
limited use in the author's view.


ALLOCATORS AND DEALLOCATORS
---------------------------

(GtStr N)

Space for a string of upper bound N.  Returns a machine
pointer.  Header is initialized, last byte cleared.

(GtConstStr N)

Like GtStr, but gets space in BPS (using GtBPS).  Used for print
name storage of INTERNed IDs.

(GtHalfWords N) (GtVect N) (GtEvect N) (GtWrds N)

Gets enough heap space for an object of upper bound N and
initializes the header.

(GtBPS N)

Gets N items of BPS (from the bottom).  Returns a machine pointer.

(DelBPS Bottom Top)

Returns the space from bottom up to (not including) top, provided
that it is the last space allocated but not deallocated
(stack-like).

(GtWarray N)

Gets N words of BPS, but from the opposite end to GtBPS.

(DelWarray Bottom Top)

Returns WArray space like DelBPS does BPS.


UPPER BOUNDS OF COMPOUND TYPES
------------------------------

(StrLen ByteLen VecLen EVecLen WrdLen HalfWordLen)

Given a machine pointer to an object of the suggested type,
returns the upper bound on indexes permitted for the object.


ELEMENT RETRIEVAL
-----------------

(StrByte U N)

U is a machine pointer to a string.  Retrieves the Nth byte.

(VecItm U N) (EVecItm U N) (WrdItm U N) (HalfWordItem U N)

Returns the Nth element given a machine pointer U.


WHAT?
-----

(StrBase U)

Pointer to string translated to pointer to beginning of data part
which can be accessed via Byte.

So what about VectBase, etc.?


FIXNUMS AND FLOATNUMS
---------------------

(FixVal U)

Gets the data part of a fixnum.

DO WE REALLY BELIEVE THIS STUFF ABOUT FLOATNUMS?

(FloatBase U)

Pointer to first word of data part of floatnum.

(FloatHighOrder U)

Gets high order part of floatnum representation.

(FloatLowOrder U)

Gets low order part of floatnum representation.

(%code-number-of-arguments U)

Gets the number of arguments information given a code pointer to
a routine.


ULTRAPRIMITIVES
---------------

The following functions appear in some system code, but are
usually not needed even by system-level programmers because other
slightly higher-level functions exist to serve most needs.  One
would use them if writing a new garbage collector, for example.

(GtHeap N)

Ultraprimitive.  Gets N items from the heap.  Returns a machine
pointer.  If an appropriate header is not installed in those
words immediately the heap could be left in an inconsistent state
and the garbage collector might break.

(PairPack dum)

Number of items in the representation of a pair.

(StrPack N) (VectPack N) (EVectPack N) (WrdPack N) (HalfWordPack N)

Number of items required to be allocated for data part of object
of N+1 elements (upper bound of N).  Many of these suffer from
"off by one" errors in the conservative direction.

Note: BytePack is missing.


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