//
// RMAC - Reboot's Macro Assembler for the Atari Jaguar Console System
// SECT.C - Code Generation, Fixups and Section Management
-// Copyright (C) 199x Landon Dyer, 2011 Reboot and Friends
+// Copyright (C) 199x Landon Dyer, 2017 Reboot and Friends
// RMAC derived from MADMAC v1.07 Written by Landon Dyer, 1986
-// Source Utilised with the Kind Permission of Landon Dyer
+// Source utilised with the kind permission of Landon Dyer
//
#include "sect.h"
// Function prototypes
-void MakeSection(int, WORD);
+void MakeSection(int, uint16_t);
void SwitchSection(int);
// Section descriptors
-SECT sect[NSECTS]; // All sections...
-int cursect; // Current section number
+SECT sect[NSECTS]; // All sections...
+int cursect; // Current section number
// These are copied from the section descriptor, the current code chunk
// descriptor and the current fixup chunk descriptor when a switch is made into
// a section. They are copied back to the descriptors when the section is left.
-WORD scattr; // Section attributes
-LONG sloc; // Current loc in section
+uint16_t scattr; // Section attributes
+uint32_t sloc; // Current loc in section
-CHUNK * scode; // Current (last) code chunk
-LONG challoc; // # bytes alloc'd to code chunk
-LONG ch_size; // # bytes used in code chunk
-char * chptr; // Deposit point in code chunk buffer
+CHUNK * scode; // Current (last) code chunk
+uint32_t challoc; // # bytes alloc'd to code chunk
+uint32_t ch_size; // # bytes used in code chunk
+uint8_t * chptr; // Deposit point in code chunk buffer
+uint8_t * chptr_opcode; // Backup of chptr, updated before entering code generators
-CHUNK * sfix; // Current (last) fixup chunk
-LONG fchalloc; // # bytes alloc'd to fixup chunk
-LONG fchsize; // # bytes used in fixup chunk
-PTR fchptr; // Deposit point in fixup chunk buffer
+CHUNK * sfix; // Current (last) fixup chunk
+uint32_t fchalloc; // # bytes alloc'd to fixup chunk
+uint32_t fchsize; // # bytes used in fixup chunk
+PTR fchptr; // Deposit point in fixup chunk buffer
// Return a size (SIZB, SIZW, SIZL) or 0, depending on what kind of fixup is
// associated with a location.
-static char fusiztab[] = {
+static uint8_t fusiztab[] = {
0, // FU_QUICK
1, // FU_BYTE
2, // FU_WORD
};
// Offset to REAL fixup location
-static char fusizoffs[] = {
+static uint8_t fusizoffs[] = {
0, // FU_QUICK
0, // FU_BYTE
0, // FU_WORD
//
-// Initialize Sections; Setup initial ABS, TEXT, DATA and BSS sections
+// Initialize sections; setup initial ABS, TEXT, DATA and BSS sections
//
void InitSection(void)
{
MakeSection(i, 0);
// Construct default sections, make TEXT the current section
- MakeSection(ABS, SUSED | SABS | SBSS); // ABS
- MakeSection(TEXT, SUSED | TEXT ); // TEXT
- MakeSection(DATA, SUSED | DATA ); // DATA
- MakeSection(BSS, SUSED | BSS | SBSS); // BSS
+ MakeSection(ABS, SUSED | SABS | SBSS); // ABS
+ MakeSection(TEXT, SUSED | TEXT ); // TEXT
+ MakeSection(DATA, SUSED | DATA ); // DATA
+ MakeSection(BSS, SUSED | BSS | SBSS); // BSS
// MakeSection(M6502, SUSED | TEXT ); // 6502 code section
- SwitchSection(TEXT); // Switch to TEXT for starters
+ // Switch to TEXT for starters
+ SwitchSection(TEXT);
}
//
-// Make a New (Clean) Section
+// Make a new (clean) section
//
-void MakeSection(int sno, WORD attr)
+void MakeSection(int sno, uint16_t attr)
{
SECT * p = §[sno];
p->scattr = attr;
//
void SwitchSection(int sno)
{
- CHUNK * cp; // Chunk pointer
+ CHUNK * cp;
cursect = sno;
SECT * p = §[sno];
- scattr = p->scattr; // Copy section vars
+ // Copy section vars
+ scattr = p->scattr;
sloc = p->sloc;
scode = p->scode;
sfix = p->sfix;
else
challoc = ch_size = 0;
- // Copy fixup chunk vars
+ // Copy fixup chunk vars
if ((cp = sfix) != NULL)
{
fchalloc = cp->challoc;
// Test to see if a location has a fixup sic'd on it. This is used by the
// listing generator to print 'xx's instead of '00's for forward references
//
-int fixtest(int sno, LONG loc)
+int fixtest(int sno, uint32_t loc)
{
- CHUNK * ch;
PTR fup;
- char * fuend;
- WORD w;
- LONG xloc;
- stopmark(); // Force update to sect[] variables
+ // Force update to sect[] variables
+ StopMark();
- // Hairy, ugly linear search for a mark on our location;
- // the speed doesn't matter, since this is only done when generating a
- // listing, which is SLOW.
- for(ch=sect[sno].sffix; ch!=NULL; ch=ch->chnext)
+ // Hairy, ugly linear search for a mark on our location; the speed doesn't
+ // matter, since this is only done when generating a listing, which is
+ // SLOW.
+ for(CHUNK * ch=sect[sno].sffix; ch!=NULL; ch=ch->chnext)
{
- fup.cp = (char *)ch->chptr;
- fuend = fup.cp + ch->ch_size;
+ fup.cp = (uint8_t *)ch->chptr;
+ uint8_t * fuend = fup.cp + ch->ch_size;
while (fup.cp < fuend)
{
- w = *fup.wp++;
- xloc = *fup.lp++ + (int)fusizoffs[w & FUMASK];
+ uint16_t w = *fup.wp++;
+ uint32_t xloc = *fup.lp++ + (int)fusizoffs[w & FUMASK];
fup.wp += 2;
if (xloc == loc)
fup.lp += w;
}
else
- ++fup.lp;
+ fup.lp++;
}
}
}
-//
-// Check that there are at least `amt' bytes left in the current chunk. If
-// there are not, allocate another chunk of at least `amt' bytes (and probably
+//
+// Check that there are at least 'amt' bytes left in the current chunk. If
+// there are not, allocate another chunk of at least 'amt' bytes (and probably
// more).
-//
-// If `amt' is zero, ensure there are at least CH_THRESHOLD bytes, likewise.
//
-int chcheck(LONG amt)
+// If 'amt' is zero, ensure there are at least CH_THRESHOLD bytes, likewise.
+//
+int chcheck(uint32_t amt)
{
DEBUG { printf("chcheck(%u)\n", amt); }
// If in BSS section, no allocation required
amt = CH_THRESHOLD;
DEBUG { printf(" challoc=%i, ch_size=%i, diff=%i\n", challoc, ch_size, challoc-ch_size); }
- if ((int)(challoc - ch_size) >= (int)amt)
+ if ((int)(challoc - ch_size) >= (int)amt)
return 0;
if (amt < CH_CODE_SIZE)
{
cp->chprev = scode;
scode->chnext = cp;
- scode->ch_size = ch_size; // Save old chunk's globals
+ scode->ch_size = ch_size; // Save old chunk's globals
}
// Setup chunk and global vars
cp->chnext = NULL;
challoc = cp->challoc = amt;
ch_size = cp->ch_size = 0;
- chptr = cp->chptr = ((char *)cp) + sizeof(CHUNK);
+ chptr = cp->chptr = ((uint8_t *)cp) + sizeof(CHUNK);
scode = p->scode = cp;
return 0;
}
-// This is really wrong. We need to make some proper structures here so we don't
-// have to count sizes of objects, that's what the compiler's for! :-P
-#define FIXUP_BASE_SIZE (sizeof(WORD) + sizeof(LONG) + sizeof(WORD) + sizeof(WORD))
+// This is really wrong. We need to make some proper structures here so we
+// don't have to count sizes of objects, that's what the compiler's for! :-P
+#define FIXUP_BASE_SIZE (sizeof(uint16_t) + sizeof(uint32_t) + sizeof(uint16_t) + sizeof(uint16_t))
//
// Arrange for a fixup on a location
//
-int AddFixup(WORD attr, LONG loc, TOKEN * fexpr)
+int AddFixup(uint16_t attr, uint32_t loc, TOKEN * fexpr)
{
- LONG i;
- LONG len = 0;
+ uint32_t i;
+ uint32_t len = 0;
CHUNK * cp;
SECT * p;
- // Shamus: Expression lengths are voodoo ATM (variable "i"). Need to fix this.
-#warning "!!! AddFixup() is filled with VOODOO !!!"
+ // Shamus: Expression lengths are voodoo ATM (variable "i"). Need to fix
+ // this.
+WARNING(!!! AddFixup() is filled with VOODOO !!!)
DEBUG printf("FIXUP@$%X: $%X\n", loc, attr);
// Compute length of expression (could be faster); determine if it's the
if (*fexpr == SYMBOL && fexpr[2] == ENDEXPR)
{
// Just a single symbol
- // SCPCD : correct bit mask for attr (else other FU_xxx will match) NYAN !
+ // SCPCD : correct bit mask for attr (else other FU_xxx will match)
+ // NYAN !
if ((attr & FUMASKRISC) == FU_JR)
{
+//printf("AddFixup: ((attr & FUMASKRISC) == FU_JR)\n");
// i = 18;
-// i = FIXUP_BASE_SIZE + (sizeof(LONG) * 2);
- i = FIXUP_BASE_SIZE + sizeof(SYM *) + sizeof(LONG);
+// i = FIXUP_BASE_SIZE + (sizeof(uint32_t) * 2);
+ i = FIXUP_BASE_SIZE + sizeof(SYM *) + sizeof(uint32_t);
}
else
{
+//printf("AddFixup: ((attr & FUMASKRISC) == FU_JR) ELSE\n");
// i = 14;
i = FIXUP_BASE_SIZE + sizeof(SYM *);
}
}
else
{
+//printf("AddFixup: !SYMBOL\n");
attr |= FU_EXPR;
for(len=0; fexpr[len]!=ENDEXPR; len++)
len++;
}
- len++; // Add 1 for ENDEXPR
+ len++; // Add 1 for ENDEXPR
// i = (len << 2) + 12;
- i = FIXUP_BASE_SIZE + sizeof(WORD) + (len * sizeof(TOKEN));
+ i = FIXUP_BASE_SIZE + sizeof(uint16_t) + (len * sizeof(TOKEN));
}
- // Maybe alloc another fixup chunk for this one to fit in
+ // Alloc another fixup chunk for this one to fit in if necessary
if ((fchalloc - fchsize) < i)
{
p = §[cursect];
cp->chnext = NULL;
fchalloc = cp->challoc = CH_FIXUP_SIZE;
fchsize = cp->ch_size = 0;
- fchptr.cp = cp->chptr = ((char *)cp) + sizeof(CHUNK);
+ fchptr.cp = cp->chptr = ((uint8_t *)cp) + sizeof(CHUNK);
sfix = p->sfix = cp;
}
*fchptr.wp++ = attr;
*fchptr.lp++ = loc;
*fchptr.wp++ = cfileno;
- *fchptr.wp++ = (WORD)curlineno;
+ *fchptr.wp++ = (uint16_t)curlineno;
// Store postfix expression or pointer to a single symbol, or nothing for a
// mark.
if (attr & FU_EXPR)
{
- *fchptr.wp++ = (WORD)len;
+ *fchptr.wp++ = (uint16_t)len;
while (len--)
- *fchptr.lp++ = (LONG)*fexpr++;
+ *fchptr.lp++ = (uint32_t)*fexpr++;
}
else
{
-// *fchptr.lp++ = (LONG)fexpr[1];
*fchptr.sy++ = symbolPtr[fexpr[1]];
+//printf("AddFixup: adding symbol (%s) [%08X]\n", symbolPtr[fexpr[1]]->sname, symbolPtr[fexpr[1]]->sattr);
}
// SCPCD : correct bit mask for attr (else other FU_xxx will match) NYAN !
//
-// Resolve all Fixups
-//
-int ResolveAllFixups(void)
-{
- unsigned i;
- char buf[EBUFSIZ];
-
- // Make undefined symbols GLOBL
- if (glob_flag)
- syg_fix();
-
- DEBUG printf("Resolving TEXT sections...\n");
- ResolveFixups(TEXT);
- DEBUG printf("Resolving DATA sections...\n");
- ResolveFixups(DATA);
-
- return 0;
-}
-
-
-//
-// Resolve Fixups in a Section
+// Resolve fixups in a section
//
int ResolveFixups(int sno)
{
- PTR fup; // Current fixup
- WORD * fuend; // End of last fixup (in this chunk)
- WORD w; // Fixup word (type+modes+flags)
- char * locp; // Location to fix (in cached chunk)
- LONG loc; // Location to fixup
- VALUE eval; // Expression value
- WORD eattr; // Expression attrib
- SYM * esym; // External symbol involved in expr
- SYM * sy; // (Temp) pointer to a symbol
- WORD i; // (Temp) word
- WORD tdb; // eattr & TDB
- LONG oaddr;
+ PTR fup; // Current fixup
+ uint16_t * fuend; // End of last fixup (in this chunk)
+ uint16_t w; // Fixup word (type+modes+flags)
+ uint8_t * locp; // Location to fix (in cached chunk)
+ uint32_t loc; // Location to fixup
+ VALUE eval; // Expression value
+ uint16_t eattr; // Expression attrib
+ SYM * esym; // External symbol involved in expr
+ SYM * sy; // (Temp) pointer to a symbol
+ uint16_t i; // (Temp) word
+ uint16_t tdb; // eattr & TDB
+ uint32_t oaddr;
int reg2;
- WORD flags;
- unsigned page_jump = 0;
- unsigned address = 0;
- unsigned j;
- char buf[EBUFSIZ];
-
+ uint16_t flags;
+
SECT * sc = §[sno];
CHUNK * ch = sc->sffix;
// "Cache" first chunk
CHUNK * cch = sc->sfcode;
- // Can't fixup a sect with nothing in it
+ // Can't fixup a section with nothing in it
if (cch == NULL)
return 0;
do
{
fup.cp = ch->chptr; // fup -> start of chunk
- fuend = (WORD *)(fup.cp + ch->ch_size); // fuend -> end of chunk
+ fuend = (uint16_t *)(fup.cp + ch->ch_size); // fuend -> end of chunk
while (fup.wp < fuend)
{
loc = *fup.lp++;
cfileno = *fup.wp++;
curlineno = (int)*fup.wp++;
-DEBUG { printf("ResolveFixups: cfileno=%u\n", cfileno); }
+ DEBUG { printf("ResolveFixups: cfileno=%u\n", cfileno); }
+
// This is based on global vars cfileno, curfname :-P
- // This approach is kinda meh as well. I think we can do better than this.
+ // This approach is kinda meh as well. I think we can do better
+ // than this.
SetFilenameForErrorReporting();
esym = NULL;
// Search for chunk containing location to fix up; compute a
// pointer to the location (in the chunk). Often we will find the
- // fixup is in the "cached" chunk, so the linear-search is seldom
+ // Fixup is in the "cached" chunk, so the linear-search is seldom
// executed.
if (loc < cch->chloc || loc >= (cch->chloc + cch->ch_size))
{
if (cch == NULL)
{
- // Fixup (loc) out of range
+ // Fixup (loc) out of range
interror(7);
// NOTREACHED
}
eattr = 0;
// Compute expression/symbol value and attribs
+
// Complex expression
if (w & FU_EXPR)
{
else
eval = 0;
+ // If the symbol is not defined, but global, set esym to sy
if ((eattr & (GLOBAL | DEFINED)) == GLOBAL)
esym = sy;
}
- tdb = (WORD)(eattr & TDB);
+ tdb = (uint16_t)(eattr & TDB);
// If the expression is undefined and no external symbol is
- // involved, then it's an error.
+ // involved, then that's an error.
if (!(eattr & DEFINED) && (esym == NULL))
{
error(undef_error);
continue;
}
-// It seems that this is completely unnecessary!
-#if 0
- if (((w & FUMASKRISC) == FU_MOVEI) && esym)
-//{
-//printf("DoFixups: Setting symbol attre to RISCSYM...\n");
- esym->sattre |= RISCSYM;
-//}
-#endif
-
// Do the fixup
- //
+ //
// If a PC-relative fixup is undefined, its value is *not*
// subtracted from the location (that will happen in the linker
// when the external reference is resolved).
- //
+ //
// MWC expects PC-relative things to have the LOC subtracted from
// the value, if the value is external (that is, undefined at this
// point).
- //
+ //
// PC-relative fixups must be DEFINED and either in the same
// section (whereupon the subtraction takes place) or ABS (with no
// subtract).
eval -= 2;
if (eval + 0x80 >= 0x100)
- goto range;
+ goto rangeErr;
if (eval == 0)
{
continue;
}
- *++locp = (char)eval;
+ *++locp = (uint8_t)eval;
break;
// Fixup one-byte value at locp + 1.
case FU_WBYTE:
}
if ((w & FU_PCREL) && eval + 0x80 >= 0x100)
- goto range;
+ goto rangeErr;
if (w & FU_SEXT)
{
if (eval + 0x100 >= 0x200)
- goto range;
+ goto rangeErr;
}
else if (eval >= 0x100)
- goto range;
+ goto rangeErr;
- *locp = (char)eval;
+ *locp = (uint8_t)eval;
break;
- // Fixup WORD forward references;
+ // Fixup WORD forward references;
// the word could be unaligned in the section buffer, so we have to
// be careful.
case FU_WORD:
- if ((w & FUMASKRISC) == FU_JR)// || ((w & 0x0F00) == FU_MJR))
+ if ((w & FUMASKRISC) == FU_JR)
{
oaddr = *fup.lp++;
else
reg2 = (signed)((eval - (loc + 2)) / 2);// & 0x1F;
-#if 0
- if ((w & 0x0F00) == FU_MJR)
- {
- // Main code destination alignment checking here for
- // forward declared labels
- address = (oaddr) ? oaddr : loc;
-
- if (((address >= 0xF03000) && (address < 0xF04000)
- && (eval < 0xF03000)) || ((eval >= 0xF03000)
- && (eval < 0xF04000) && (address < 0xF03000)))
- {
- warni("* \'jr\' at $%08X - cannot jump relative between "
- "main memory and local gpu ram", address);
- }
- else
- {
- page_jump = (address & 0xFFFFFF00) - (eval & 0xFFFFFF00);
-
- if (page_jump)
- {
- // This jump is to a page outside of the
- // current 256 byte page
- if (eval % 4)
- {
- warni("* \'jr\' at $%08X - destination address not aligned for long page jump, insert a \'nop\' before the destination address", address);
- }
- }
- else
- {
- // This jump is in the current 256 byte page
- if ((eval - 2) % 4)
- {
- warni("* \'jr\' at $%08X - destination address not aligned for short page jump, insert a \'nop\' before the destination address", address);
- }
- }
- }
- }
-#endif
-
if ((reg2 < -16) || (reg2 > 15))
{
error("relative jump out of range");
break;
}
- *locp = (char)(*locp | ((reg2 >> 3) & 0x03));
+ *locp = (uint8_t)(*locp | ((reg2 >> 3) & 0x03));
locp++;
- *locp = (char)(*locp | ((reg2 & 0x07) << 5));
+ *locp = (uint8_t)(*locp | ((reg2 & 0x07) << 5));
break;
}
break;
}
- *locp = (char)(*locp | ((eval >> 3) & 0x03));
+ *locp = (uint8_t)(*locp | ((eval >> 3) & 0x03));
locp++;
- *locp = (char)(*locp | ((eval & 0x07) << 5));
+ *locp = (uint8_t)(*locp | ((eval & 0x07) << 5));
break;
}
break;
}
- *locp = (char)(*locp | ((eval >> 3) & 0x03));
+ *locp = (uint8_t)(*locp | ((eval >> 3) & 0x03));
locp++;
- *locp = (char)(*locp | ((eval & 0x07) << 5));
+ *locp = (uint8_t)(*locp | ((eval & 0x07) << 5));
break;
}
eval = (32 - eval);
eval = (eval == 32) ? 0 : eval;
- *locp = (char)(*locp | ((eval >> 3) & 0x03));
+ *locp = (uint8_t)(*locp | ((eval >> 3) & 0x03));
locp++;
- *locp = (char)(*locp | ((eval & 0x07) << 5));
+ *locp = (uint8_t)(*locp | ((eval & 0x07) << 5));
break;
}
break;
}
- *locp = (char)(*locp | ((eval >> 3) & 0x03));
+ *locp = (uint8_t)(*locp | ((eval >> 3) & 0x03));
locp++;
- *locp = (char)(*locp | ((eval & 0x07) << 5));
+ *locp = (uint8_t)(*locp | ((eval & 0x07) << 5));
break;
}
}
locp++;
- *locp = (char)(*locp | (eval & 0x1F));
+ *locp = (uint8_t)(*locp | (eval & 0x1F));
break;
}
if (!(eattr & DEFINED))
{
+ flags = MWORD;
+
if (w & FU_PCREL)
- w = MPCREL | MWORD;
- else
- w = MWORD;
+ flags |= MPCREL;
- rmark(sno, loc, 0, w, esym);
+ MarkRelocatable(sno, loc, 0, flags, esym);
}
else
{
if (tdb)
- rmark(sno, loc, tdb, MWORD, NULL);
+ MarkRelocatable(sno, loc, tdb, MWORD, NULL);
if (w & FU_SEXT)
{
if (eval + 0x10000 >= 0x20000)
- goto range;
+ goto rangeErr;
}
else
{
if (w & FU_ISBRA)
{
if (eval + 0x8000 >= 0x10000)
- goto range;
+ goto rangeErr;
}
else if (eval >= 0x10000)
- goto range;
+ goto rangeErr;
}
}
- *locp++ = (char)(eval >> 8);
- *locp = (char)eval;
+ SETBE16(locp, 0, eval);
break;
// Fixup LONG forward references;
// the long could be unaligned in the section buffer, so be careful
// (again).
case FU_LONG:
+ flags = MLONG;
+
if ((w & FUMASKRISC) == FU_MOVEI)
{
-#if 0
- address = loc + 4;
-
- if (eattr & DEFINED)
- {
- for(j=0; j<fwindex; j++)
- {
- if (fwdjump[j] == address)
- {
- page_jump = (address & 0xFFFFFF00) - (eval & 0xFFFFFF00);
-
- if (page_jump)
- {
- if (eval % 4)
- {
- err_setup();
- sprintf(buf, "* \'jump\' at $%08X - destination address not aligned for long page jump, insert a \'nop\' before the destination address", address);
-
- if (listing > 0)
- ship_ln(buf);
-
- if (err_flag)
- write(err_fd, buf, (LONG)strlen(buf));
- else
- printf("%s\n", buf);
- }
- }
- else
- {
- if (!(eval & 0x0000000F) || ((eval - 2) % 4))
- {
- err_setup();
- sprintf(buf, "* \'jump\' at $%08X - destination address not aligned for short page jump, insert a \'nop\' before the destination address", address);
-
- if (listing > 0)
- ship_ln(buf);
-
- if (err_flag)
- write(err_fd, buf, (LONG)strlen(buf));
- else
- printf("%s\n", buf);
- }
- }
-
- // Clear this jump as it has been checked
- fwdjump[j] = 0;
- j = fwindex;
- }
- }
- }
-#endif
-
// Long constant in MOVEI # is word-swapped, so fix it here
- eval = ((eval >> 16) & 0x0000FFFF) | ((eval << 16) & 0xFFFF0000);
- flags = (MLONG | MMOVEI);
+ eval = WORDSWAP32(eval);
+ flags |= MMOVEI;
}
- else
- flags = MLONG;
+ // If the symbol is undefined, make sure to pass the symbol in
+ // to the MarkRelocatable() function.
if (!(eattr & DEFINED))
- {
-//printf("Fixup (long): Symbol undefined. loc = $%X, long = $%X, flags = $%x\n", loc, eval, flags);
- rmark(sno, loc, 0, flags, esym);
- }
+ MarkRelocatable(sno, loc, 0, flags, esym);
else if (tdb)
- {
-//printf("Fixup (long): TDB = $%X. loc =$%X, long = $%X, flags = $%x\n", tdb, loc, eval, flags);
- rmark(sno, loc, tdb, flags, NULL);
- }
-//else
-//printf("Fixup (long): TDB = $%X. loc =$%X, long = $%X, flags = $%x\n", tdb, loc, eval, flags);
+ MarkRelocatable(sno, loc, tdb, flags, NULL);
- *locp++ = (char)(eval >> 24);
- *locp++ = (char)(eval >> 16);
- *locp++ = (char)(eval >> 8);
- *locp = (char)eval;
+ SETBE32(locp, 0, eval);
break;
// Fixup a 3-bit "QUICK" reference in bits 9..1
- // (range of 1..8) in a word. Really bits 1..3 in a byte.
+ // (range of 1..8) in a word. Really bits 1..3 in a byte.
case FU_QUICK:
if (!(eattr & DEFINED))
{
}
if (eval < 1 || eval > 8)
- goto range;
+ goto rangeErr;
*locp |= (eval & 7) << 1;
break;
eval -= (loc + 1);
if (eval + 0x80 >= 0x100)
- goto range;
+ goto rangeErr;
- *locp = (char)eval;
+ *locp = (uint8_t)eval;
break;
default:
- interror(4); // Bad fixup type
+ // Bad fixup type--this should *never* happen!
+ interror(4);
// NOTREACHED
}
continue;
-range:
+rangeErr:
error("expression out of range");
}
return 0;
}
+//
+// Resolve all fixups
+//
+int ResolveAllFixups(void)
+{
+ // Make undefined symbols GLOBL
+ if (glob_flag)
+ ForceUndefinedSymbolsGlobal();
+
+ DEBUG printf("Resolving TEXT sections...\n");
+ ResolveFixups(TEXT);
+ DEBUG printf("Resolving DATA sections...\n");
+ ResolveFixups(DATA);
+
+ return 0;
+}
+