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littlest
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littl-st.lha
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primitive.c
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1993-08-10
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/*
Little Smalltalk, version 3
Written by Tim Budd, Oregon State University, July 1988
Primitive processor
primitives are how actions are ultimately executed in the Smalltalk
system.
unlike ST-80, Little Smalltalk primitives cannot fail (although
they can return nil, and methods can take this as an indication
of failure). In this respect primitives in Little Smalltalk are
much more like traditional system calls.
Primitives are combined into groups of 10 according to
argument count and type, and in some cases type checking is performed.
IMPORTANT NOTE:
The technique used to tell if an arithmetic operation
has overflowed in intBinary() depends upon integers
being 16 bits. If this is not true, other techniques
may be required.
system specific I/O primitives are found in a different file.
*/
# include <stdio.h>
# include <math.h>
# include "env.h"
# include "memory.h"
# include "names.h"
# ifdef STRING
# include <string.h>
# endif
# ifdef STRINGS
# include <strings.h>
# endif
# ifdef SIGNAL
# include <signal.h>
# include <setjmp.h>
# endif
# ifdef CTRLBRK
# include <dos.h>
# include <signal.h>
# include <setjmp.h>
# endif
extern object processStack;
extern int linkPointer;
extern double frexp(), ldexp();
extern long time();
extern object ioPrimitive(INT X OBJP);
extern object sysPrimitive(INT X OBJP);
# ifdef SIGNAL
static jmp_buf jb;
brkfun() { longjmp(jb, 1); }
brkignore() {;}
# endif
# ifdef CTRLBRK
static jmp_buf jb;
brkfun() { longjmp(jb, 1); }
brkignore() {;}
# endif
static object zeroaryPrims(number)
int number;
{ short i;
object returnedObject;
int objectCount();
returnedObject = nilobj;
switch(number) {
case 1:
fprintf(stderr,"did primitive 1\n");
break;
case 2:
fprintf(stderr,"object count %d\n", objectCount());
break;
case 3: /* return a random number */
/* this is hacked because of the representation */
/* of integers as shorts */
i = rand() >> 8; /* strip off lower bits */
if (i < 0) i = - i;
returnedObject = newInteger(i>>1);
break;
case 4: /* return time in seconds */
i = (short) time((long *) 0);
returnedObject = newInteger(i);
break;
case 5: /* flip watch - done in interp */
break;
case 9:
exit(0);
default: /* unknown primitive */
sysError("unknown primitive","zeroargPrims");
break;
}
return(returnedObject);
}
static int unaryPrims(number, firstarg)
int number;
object firstarg;
{ int i, j, saveLinkPointer;
object returnedObject, saveProcessStack;
returnedObject = firstarg;
switch(number) {
case 1: /* class of object */
returnedObject = getClass(firstarg);
break;
case 2: /* basic size of object */
if (isInteger(firstarg))
i = 0;
else {
i = sizeField(firstarg);
/* byte objects have negative size */
if (i < 0) i = (-i);
}
returnedObject = newInteger(i);
break;
case 3: /* hash value of object */
if (isInteger(firstarg))
returnedObject = firstarg;
else
returnedObject = newInteger(firstarg);
break;
case 4: /* debugging print */
fprintf(stderr,"primitive 14 %d\n", firstarg);
break;
case 8: /* change return point - block return */
/* first get previous link pointer */
i = intValue(basicAt(processStack, linkPointer));
/* then creating context pointer */
j = intValue(basicAt(firstarg, 1));
if (basicAt(processStack, j+1) != firstarg) {
returnedObject = falseobj;
break;
}
/* first change link pointer to that of creator */
fieldAtPut(processStack, i,
basicAt(processStack, j));
/* then change return point to that of creator */
fieldAtPut(processStack, i+2,
basicAt(processStack, j+2));
returnedObject = trueobj;
break;
case 9: /* process execute */
/* first save the values we are about to clobber */
saveProcessStack = processStack;
saveLinkPointer = linkPointer;
# ifdef SIGNAL
/* trap control-C */
signal(SIGINT, brkfun);
if (setjmp(jb)) {
returnedObject = falseobj;
}
else
# endif
# ifdef CRTLBRK
/* trap control-C using dos ctrlbrk routine */
ctrlbrk(brkfun);
if (setjmp(jb)) {
returnedObject = falseobj;
}
else
# endif
if (execute(firstarg, 5000))
returnedObject = trueobj;
else
returnedObject = falseobj;
/* then restore previous environment */
processStack = saveProcessStack;
linkPointer = saveLinkPointer;
# ifdef SIGNAL
signal(SIGINT, brkignore);
# endif
# ifdef CTRLBRK
ctrlbrk(brkignore);
# endif
break;
default: /* unknown primitive */
sysError("unknown primitive","unaryPrims");
break;
}
return(returnedObject);
}
static int binaryPrims(number, firstarg, secondarg)
int number;
object firstarg, secondarg;
{ char buffer[2000];
int i;
object returnedObject;
returnedObject = firstarg;
switch(number) {
case 1: /* object identity test */
if (firstarg == secondarg)
returnedObject = trueobj;
else
returnedObject = falseobj;
break;
case 2: /* set class of object */
decr(classField(firstarg));
setClass(firstarg, secondarg);
returnedObject = firstarg;
break;
case 3: /* debugging stuff */
fprintf(stderr,"primitive 23 %d %d\n", firstarg, secondarg);
break;
case 4: /* string cat */
ignore strcpy(buffer, charPtr(firstarg));
ignore strcat(buffer, charPtr(secondarg));
returnedObject = newStString(buffer);
break;
case 5: /* basicAt: */
if (! isInteger(secondarg))
sysError("non integer index","basicAt:");
returnedObject = basicAt(firstarg, intValue(secondarg));
break;
case 6: /* byteAt: */
if (! isInteger(secondarg))
sysError("non integer index","byteAt:");
i = byteAt(firstarg, intValue(secondarg));
if (i < 0) i += 256;
returnedObject = newInteger(i);
break;
case 7: /* symbol set */
nameTableInsert(symbols, strHash(charPtr(firstarg)),
firstarg, secondarg);
break;
case 8: /* block start */
/* first get previous link */
i = intValue(basicAt(processStack, linkPointer));
/* change context and byte pointer */
fieldAtPut(processStack, i+1, firstarg);
fieldAtPut(processStack, i+4, secondarg);
break;
case 9: /* duplicate a block, adding a new context to it */
returnedObject = newBlock();
basicAtPut(returnedObject, 1, secondarg);
basicAtPut(returnedObject, 2, basicAt(firstarg, 2));
basicAtPut(returnedObject, 3, basicAt(firstarg, 3));
basicAtPut(returnedObject, 4, basicAt(firstarg, 4));
break;
default: /* unknown primitive */
sysError("unknown primitive","binaryPrims");
break;
}
return(returnedObject);
}
static int trinaryPrims(number, firstarg, secondarg, thirdarg)
int number;
object firstarg, secondarg, thirdarg;
{ char *bp, *tp, buffer[256];
int i, j;
object returnedObject;
returnedObject = firstarg;
switch(number) {
case 1: /* basicAt:Put: */
if (! isInteger(secondarg))
sysError("non integer index","basicAtPut");
fprintf(stderr,"IN BASICATPUT %d %d %d\n", firstarg, intValue(secondarg), thirdarg);
fieldAtPut(firstarg, intValue(secondarg), thirdarg);
break;
case 2: /* basicAt:Put: for bytes */
if (! isInteger(secondarg))
sysError("non integer index","byteAtPut");
if (! isInteger(thirdarg))
sysError("assigning non int","to byte");
byteAtPut(firstarg, intValue(secondarg),
intValue(thirdarg));
break;
case 3: /* string copyFrom:to: */
bp = charPtr(firstarg);
if ((! isInteger(secondarg)) || (! isInteger(thirdarg)))
sysError("non integer index","copyFromTo");
i = intValue(secondarg);
j = intValue(thirdarg);
tp = buffer;
if (i <= strlen(bp))
for ( ; (i <= j) && bp[i-1]; i++)
*tp++ = bp[i-1];
*tp = '\0';
returnedObject = newStString(buffer);
break;
case 9: /* compile method */
setInstanceVariables(firstarg);
if (parse(thirdarg, charPtr(secondarg), false)) {
flushCache(basicAt(thirdarg, messageInMethod), firstarg);
returnedObject = trueobj;
}
else
returnedObject = falseobj;
break;
default: /* unknown primitive */
sysError("unknown primitive","trinaryPrims");
break;
}
return(returnedObject);
}
static int intUnary(number, firstarg)
int number, firstarg;
{ object returnedObject;
switch(number) {
case 1: /* float equiv of integer */
returnedObject = newFloat((double) firstarg);
break;
case 2: /* print - for debugging purposes */
fprintf(stderr,"debugging print %d\n", firstarg);
break;
case 3: /* set time slice - done in interpreter */
break;
case 5: /* set random number */
ignore srand((unsigned) firstarg);
returnedObject = nilobj;
break;
case 8:
returnedObject = allocObject(firstarg);
break;
case 9:
returnedObject = allocByte(firstarg);
break;
default:
sysError("intUnary primitive","not implemented yet");
}
return(returnedObject);
}
static object intBinary(number, firstarg, secondarg)
register int firstarg, secondarg;
int number;
{ boolean binresult;
long longresult;
object returnedObject;
switch(number) {
case 0: /* addition */
longresult = firstarg;
longresult += secondarg;
if (longCanBeInt(longresult))
firstarg = longresult;
else
goto overflow;
break;
case 1: /* subtraction */
longresult = firstarg;
longresult -= secondarg;
if (longCanBeInt(longresult))
firstarg = longresult;
else
goto overflow;
break;
case 2: /* relationals */
binresult = firstarg < secondarg; break;
case 3:
binresult = firstarg > secondarg; break;
case 4:
binresult = firstarg <= secondarg; break;
case 5:
binresult = firstarg >= secondarg; break;
case 6: case 13:
binresult = firstarg == secondarg; break;
case 7:
binresult = firstarg != secondarg; break;
case 8: /* multiplication */
longresult = firstarg;
longresult *= secondarg;
if (longCanBeInt(longresult))
firstarg = longresult;
else
goto overflow;
break;
case 9: /* quo: */
if (secondarg == 0) goto overflow;
firstarg /= secondarg; break;
case 10: /* rem: */
if (secondarg == 0) goto overflow;
firstarg %= secondarg; break;
case 11: /* bit operations */
firstarg &= secondarg; break;
case 12:
firstarg ^= secondarg; break;
case 19: /* shifts */
if (secondarg < 0)
firstarg >>= (- secondarg);
else
firstarg <<= secondarg;
break;
}
if ((number >= 2) && (number <= 7))
if (binresult)
returnedObject = trueobj;
else
returnedObject = falseobj;
else
returnedObject = newInteger(firstarg);
return(returnedObject);
/* on overflow, return nil and let smalltalk code */
/* figure out what to do */
overflow:
returnedObject = nilobj;
return(returnedObject);
}
static int strUnary(number, firstargument)
int number;
char *firstargument;
{ object returnedObject;
switch(number) {
case 1: /* length of string */
returnedObject = newInteger(strlen(firstargument));
break;
case 2: /* hash value of symbol */
returnedObject = newInteger(strHash(firstargument));
break;
case 3: /* string as symbol */
returnedObject = newSymbol(firstargument);
break;
case 7: /* value of symbol */
returnedObject = globalSymbol(firstargument);
break;
case 8:
# ifndef NOSYSTEM
returnedObject = newInteger(system(firstargument));
# endif
break;
case 9:
sysError("fatal error", firstargument);
break;
default:
sysError("unknown primitive", "strUnary");
break;
}
return(returnedObject);
}
static int floatUnary(number, firstarg)
int number;
double firstarg;
{ char buffer[20];
double temp;
int i, j;
object returnedObject;
switch(number) {
case 1: /* floating value asString */
ignore sprintf(buffer,"%g", firstarg);
returnedObject = newStString(buffer);
break;
case 2: /* log */
returnedObject = newFloat(log(firstarg));
break;
case 3: /* exp */
returnedObject = newFloat(exp(firstarg));
break;
case 6: /* integer part */
/* return two integers n and m such that */
/* number can be written as n * 2** m */
# define ndif 12
temp = frexp(firstarg, &i);
if ((i >= 0)&&(i <= ndif)) {temp=ldexp(temp, i); i=0;}
else { i -= ndif; temp = ldexp(temp, ndif); }
j = (int) temp;
returnedObject = newArray(2);
basicAtPut(returnedObject, 1, newInteger(j));
basicAtPut(returnedObject, 2, newInteger(i));
# ifdef trynew
/* if number is too big it can't be integer anyway */
if (firstarg > 2e9)
returnedObject = nilobj;
else {
ignore modf(firstarg, &temp);
ltemp = (long) temp;
if (longCanBeInt(ltemp))
returnedObject = newInteger((int) temp);
else
returnedObject = newFloat(temp);
}
# endif
break;
default:
sysError("unknown primitive","floatUnary");
break;
}
return(returnedObject);
}
static object floatBinary(number, first, second)
int number;
double first, second;
{ boolean binResult;
object returnedObject;
switch(number) {
case 0: first += second; break;
case 1: first -= second; break;
case 2: binResult = (first < second); break;
case 3: binResult = (first > second); break;
case 4: binResult = (first <= second); break;
case 5: binResult = (first >= second); break;
case 6: binResult = (first == second); break;
case 7: binResult = (first != second); break;
case 8: first *= second; break;
case 9: first /= second; break;
default:
sysError("unknown primitive", "floatBinary");
break;
}
if ((number >= 2) && (number <= 7))
if (binResult)
returnedObject = trueobj;
else
returnedObject = falseobj;
else
returnedObject = newFloat(first);
return(returnedObject);
}
/* primitive -
the main driver for the primitive handler
*/
object primitive(primitiveNumber, arguments)
register int primitiveNumber;
object *arguments;
{ register int primitiveGroup = primitiveNumber / 10;
object returnedObject;
if (primitiveNumber >= 150) {
/* system dependent primitives, handled in separate module */
returnedObject = sysPrimitive(primitiveNumber, arguments);
}
else {
switch(primitiveGroup) {
case 0:
returnedObject = zeroaryPrims(primitiveNumber);
break;
case 1:
returnedObject = unaryPrims(primitiveNumber - 10, arguments[0]);
break;
case 2:
returnedObject = binaryPrims(primitiveNumber-20, arguments[0], arguments[1]);
break;
case 3:
returnedObject = trinaryPrims(primitiveNumber-30, arguments[0], arguments[1], arguments[2]);
break;
case 5: /* integer unary operations */
if (! isInteger(arguments[0]))
returnedObject = nilobj;
else
returnedObject = intUnary(primitiveNumber-50,
intValue(arguments[0]));
break;
case 6: case 7: /* integer binary operations */
if ((! isInteger(arguments[0])) ||
! isInteger(arguments[1]))
returnedObject = nilobj;
else
returnedObject = intBinary(primitiveNumber-60,
intValue(arguments[0]),
intValue(arguments[1]));
break;
case 8: /* string unary */
returnedObject = strUnary(primitiveNumber-80, charPtr(arguments[0]));
break;
case 10: /* float unary */
returnedObject = floatUnary(primitiveNumber-100, floatValue(arguments[0]));
break;
case 11: /* float binary */
returnedObject = floatBinary(primitiveNumber-110,
floatValue(arguments[0]),
floatValue(arguments[1]));
break;
case 12: case 13: /* file operations */
returnedObject = ioPrimitive(primitiveNumber-120, arguments);
break;
default:
sysError("unknown primitive number","doPrimitive");
break;
}
}
return (returnedObject);
}