//
-// RMAC - Reboot's Macro Assembler for the Atari Jaguar Console System
+// RMAC - Reboot's Macro Assembler for all Atari computers
// EXPR.C - Expression Analyzer
-// Copyright (C) 199x Landon Dyer, 2011 Reboot and Friends
+// Copyright (C) 199x Landon Dyer, 2011-2017 Reboot and Friends
// RMAC derived from MADMAC v1.07 Written by Landon Dyer, 1986
// Source utilised with the kind permission of Landon Dyer
//
#include "symbol.h"
#include "token.h"
-#define DEF_KW // Declare keyword values
+#define DEF_KW // Declare keyword values
#include "kwtab.h" // Incl generated keyword tables & defs
// N.B.: The size of tokenClass should be identical to the largest value of
// a token; we're assuming 256 but not 100% sure!
static char tokenClass[256]; // Generated table of token classes
-static VALUE evstk[EVSTACKSIZE]; // Evaluator value stack
+static uint32_t evstk[EVSTACKSIZE]; // Evaluator value stack
static WORD evattr[EVSTACKSIZE]; // Evaluator attribute stack
// Token-class initialization list
char itokcl[] = {
0, // END
- CONST, SYMBOL, 0, // ID
+ CONST, SYMBOL, 0, // ID
'(', '[', '{', 0, // OPAR
- ')', ']', '}', 0, // CPAR
+ ')', ']', '}', 0, // CPAR
CR_DEFINED, CR_REFERENCED, // SUNARY (special unary)
CR_STREQ, CR_MACDEF,
- CR_DATE, CR_TIME,
+ CR_DATE, CR_TIME,
CR_ABSCOUNT, 0,
'!', '~', UNMINUS, 0, // UNARY
- '*', '/', '%', 0, // MULT
- '+', '-', 0, // ADD
- SHL, SHR, 0, // SHIFT
- LE, GE, '<', '>', NE, '=', 0, // REL
- '&', 0, // AND
- '^', 0, // XOR
- '|', 0, // OR
- 1 // (the end)
+ '*', '/', '%', 0, // MULT
+ '+', '-', 0, // ADD
+ SHL, SHR, 0, // SHIFT
+ LE, GE, '<', '>', NE, '=', 0, // REL
+ '&', 0, // AND
+ '^', 0, // XOR
+ '|', 0, // OR
+ 1 // (the end)
};
const char missym_error[] = "missing symbol";
// pointer to exprbuf from direct.c)
// (Can also be from others, like
// riscasm.c)
-static symbolNum; // Pointer to the entry in symbolPtr[]
+static int symbolNum; // Pointer to the entry in symbolPtr[]
//
// Obtain a string value
//
-static VALUE str_value(char * p)
+static uint32_t str_value(char * p)
{
- VALUE v;
+ uint32_t v;
for(v=0; *p; p++)
v = (v << 8) | (*p & 0xFF);
//
void InitExpression(void)
{
- int i;
- char * p;
-
// Initialize token-class table (all set to END)
- for(i=0; i<256; i++)
+ for(int i=0; i<256; i++)
tokenClass[i] = END;
- for(i=0, p=itokcl; *p!=1; p++)
+ int i = 0;
+
+ for(char * p=itokcl; *p!=1; p++)
{
if (*p == 0)
i++;
- else
+ else
tokenClass[(int)(*p)] = (char)i;
}
if (expr1() != OK)
return ERROR;
-
+
while (tokenClass[*tok] >= MULT)
{
t = *tok++;
break;
}
}
- else
+ else
return expr2();
return OK;
// Check register bank usage
if (sy->sattre & EQUATEDREG)
{
- if ((regbank == BANK_0) && (sy->sattre & BANK_1) && !altbankok)
- warns("equated symbol \'%s\' cannot be used in register bank 0", sy->sname);
+ if ((regbank == BANK_0) && (sy->sattre & BANK_1) && !altbankok)
+ warn("equated symbol \'%s\' cannot be used in register bank 0", sy->sname);
if ((regbank == BANK_1) && (sy->sattre & BANK_0) && !altbankok)
- warns("equated symbol \'%s\' cannot be used in register bank 1", sy->sname);
+ warn("equated symbol \'%s\' cannot be used in register bank 1", sy->sname);
}
*evalTokenBuffer++ = SYMBOL;
return ERROR;
if (*tok++ != ')')
- return error("missing close parenthesis ')'");
+ return error("missing closing parenthesis ')'");
break;
case '[':
return ERROR;
if (*tok++ != ']')
- return error("missing close parenthesis ']'");
+ return error("missing closing bracket ']'");
break;
case '$':
*evalTokenBuffer++ = (orgactive ? orgaddr : pcloc);
// '*' takes attributes of current section, not ABS!
*evalTokenBuffer++ = cursect | DEFINED;
+ break;
+ case '{':
+ if (expr0() != OK) // Eat up first parameter (register or immediate)
+ return ERROR;
+
+ if (*tok++ != ':') // Demand a ':' there
+ return error("missing colon ':'");
+
+ if (expr0() != OK) // Eat up second parameter (register or immediate)
+ return ERROR;
+
+ if (*tok++ != '}')
+ return error("missing closing brace '}'");
+
break;
default:
return error("bad expression");
//
// Recursive-descent expression analyzer (with some simple speed hacks)
//
-int expr(TOKEN * otk, VALUE * a_value, WORD * a_attr, SYM ** a_esym)
+int expr(TOKEN * otk, uint32_t * a_value, WORD * a_attr, SYM ** a_esym)
{
// Passed in values (once derefenced, that is) can all be zero. They are
// there so that the expression analyzer can fill them in as needed. The
// means it will be fixed up later, and thus, not an error.
if ((symbol->sattre & UNDEF_EQUR) && !riscImmTokenSeen)
{
- errors("undefined register equate '%s'", symbol->sname);
+ error("undefined register equate '%s'", symbol->sname);
//if we return right away, it returns some spurious errors...
// return ERROR;
}
// Check register bank usage
if (symbol->sattre & EQUATEDREG)
{
- if ((regbank == BANK_0) && (symbol->sattre & BANK_1) && !altbankok)
- warns("equated symbol '%s' cannot be used in register bank 0", symbol->sname);
+ if ((regbank == BANK_0) && (symbol->sattre & BANK_1) && !altbankok)
+ warn("equated symbol '%s' cannot be used in register bank 0", symbol->sname);
if ((regbank == BANK_1) && (symbol->sattre & BANK_0) && !altbankok)
- warns("equated symbol '%s' cannot be used in register bank 1", symbol->sname);
+ warn("equated symbol '%s' cannot be used in register bank 1", symbol->sname);
}
*evalTokenBuffer++ = SYMBOL;
All that extra crap that was put into the svalue when doing the equr stuff is
thrown away right here. What the hell is it for?
*/
- if (symbol->sattre & EQUATEDREG)
+ if (symbol->sattre & EQUATEDREG)
*a_value &= 0x1F;
*a_attr = (WORD)(symbol->sattr & ~GLOBAL);
// UNDEFINED, but it's value includes everything but the symbol value, and
// `a_esym' is set to the external symbol.
//
-int evexpr(TOKEN * tk, VALUE * a_value, WORD * a_attr, SYM ** a_esym)
+int evexpr(TOKEN * tk, uint32_t * a_value, WORD * a_attr, SYM ** a_esym)
{
- WORD * sattr;
- VALUE * sval;
WORD attr;
SYM * sy;
- SYM * esym;
- WORD sym_seg;
-
- sval = evstk; // (Empty) initial stack
- sattr = evattr;
- esym = NULL; // No external symbol involved
- sym_seg = 0;
+ uint32_t * sval = evstk; // (Empty) initial stack
+ WORD * sattr = evattr;
+ SYM * esym = NULL; // No external symbol involved
+ WORD sym_seg = 0;
while (*tk != ENDEXPR)
{
case SYMBOL:
//printf("evexpr(): SYMBOL\n");
sy = symbolPtr[*tk++];
- sy->sattr |= REFERENCED; // Set "referenced" bit
+ sy->sattr |= REFERENCED; // Set "referenced" bit
if (!(sy->sattr & DEFINED))
{
}
else
{
- *++sval = 0; // 0 for undefined symbols
+ *++sval = 0; // 0 for undefined symbols
}
*++sattr = (WORD)(sy->sattr & ~GLOBAL); // Push attribs
break;
// Binary "+" and "-" matrix:
- //
+ //
// ABS Sect Other
// ----------------------------
// ABS | ABS | Sect | Other |
// Sect | Sect | [1] | Error |
// Other | Other | Error | [1] |
// ----------------------------
- //
+ //
// [1] + : Error
// - : ABS
case '+':
//printf("evexpr(): +\n");
--sval; // Pop value
- --sattr; // Pop attrib
+ --sattr; // Pop attrib
//printf("--> N+N: %i + %i = ", *sval, sval[1]);
*sval += sval[1]; // Compute value
//printf("%i\n", *sval);
case '-':
//printf("evexpr(): -\n");
--sval; // Pop value
- --sattr; // Pop attrib
+ --sattr; // Pop attrib
//printf("--> N-N: %i - %i = ", *sval, sval[1]);
*sval -= sval[1]; // Compute value
//printf("%i\n", *sval);
// are in the same segment, but that's the only requirement.
case LE:
//printf("evexpr(): LE\n");
- --sattr;
- --sval;
+ sattr--;
+ sval--;
if ((*sattr & TDB) != (sattr[1] & TDB))
error(seg_error);
break;
case GE:
//printf("evexpr(): GE\n");
- --sattr;
- --sval;
+ sattr--;
+ sval--;
if ((*sattr & TDB) != (sattr[1] & TDB))
error(seg_error);
break;
case '>':
//printf("evexpr(): >\n");
- --sattr;
- --sval;
+ sattr--;
+ sval--;
if ((*sattr & TDB) != (sattr[1] & TDB))
error(seg_error);
break;
case '<':
//printf("evexpr(): <\n");
- --sattr;
- --sval;
+ sattr--;
+ sval--;
if ((*sattr & TDB) != (sattr[1] & TDB))
error(seg_error);
break;
case NE:
//printf("evexpr(): NE\n");
- --sattr;
- --sval;
+ sattr--;
+ sval--;
if ((*sattr & TDB) != (sattr[1] & TDB))
error(seg_error);
break;
case '=':
//printf("evexpr(): =\n");
- --sattr;
- --sval;
+ sattr--;
+ sval--;
if ((*sattr & TDB) != (sattr[1] & TDB))
error(seg_error);
switch ((int)tk[-1])
{
case '*':
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
//printf("--> NxN: %i x %i = ", *sval, sval[1]);
*sval *= sval[1];
//printf("%i\n", *sval);
break;
case '/':
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
if (sval[1] == 0)
- return error("divide by zero");
+ return error("division by zero");
//printf("--> N/N: %i / %i = ", sval[0], sval[1]);
// Compiler is picky here: Without casting these, it discards
// the sign if dividing a negative # by a positive one,
// creating a bad result. :-/
- // Probably a side effect of using VALUE intead of ints.
- *sval = (int)sval[0] / (int)sval[1];
+ // Definitely a side effect of using uint32_ts intead of ints.
+ *sval = (int32_t)sval[0] / (int32_t)sval[1];
//printf("%i\n", *sval);
break;
case '%':
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
if (sval[1] == 0)
return error("mod (%) by zero");
*sval %= sval[1];
break;
case SHL:
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
*sval <<= sval[1];
break;
case SHR:
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
*sval >>= sval[1];
break;
case '&':
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
*sval &= sval[1];
break;
case '^':
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
*sval ^= sval[1];
break;
case '|':
- --sval;
- --sattr; // Pop attrib
+ sval--;
+ sattr--; // Pop attrib
*sval |= sval[1];
break;
default:
// sym_seg added in 1.0.16 to solve a problem with forward symbols in
// expressions where absolute values also existed. The absolutes were
// overiding the symbol segments and not being included :(
- //*a_attr = *sattr | sym_seg; // Copy value + attrib
+ //*a_attr = *sattr | sym_seg; // Copy value + attrib
*a_attr = *sattr; // Copy value + attrib
*a_value = *sval;