//
-// RMAC - Reboot's Macro Assembler for all Atari computers
+// RMAC - Renamed Macro Assembler for all Atari computers
// OBJECT.C - Writing Object Files
-// Copyright (C) 199x Landon Dyer, 2011-2019 Reboot and Friends
+// Copyright (C) 199x Landon Dyer, 2011-2022 Reboot and Friends
// RMAC derived from MADMAC v1.07 Written by Landon Dyer, 1986
// Source utilised with the kind permission of Landon Dyer
//
#include "object.h"
#include "6502.h"
#include "direct.h"
+#include "dsp56k.h"
#include "error.h"
#include "mark.h"
#include "riscasm.h"
#include "sect.h"
#include "symbol.h"
+#include "version.h"
//#define DEBUG_ELF
- 6-15 Currently unused
*/
+// Internal function prototypes
+static void WriteLOD(void);
+static void WriteP56(void);
//
// Add entry to symbol table (in ALCYON mode)
w |= AL_EXTERN | AL_GLOBAL; // Common symbol
w &= ~AL_BSS; // They're not BSS in Alcyon object files
}
- else if (w1 & DEFINED)
+
+ if (w1 & DEFINED)
{
if (globflag) // Export the symbol
w |= AL_GLOBAL;
return buf;
}
-
//
// Add an entry to the BSD symbol table
//
+// From stab.def (https://sites.uclouvain.be/SystInfo/usr/include/bits/stab.def.html):
+/*
+_________________________________________________
+| 00 - 1F are not dbx stab symbols |
+| In most cases, the low bit is the EXTernal bit|
+
+| 00 UNDEF | 02 ABS | 04 TEXT | 06 DATA |
+| 01 |EXT | 03 |EXT | 05 |EXT | 07 |EXT |
+
+| 08 BSS | 0A INDR | 0C FN_SEQ | 0E WEAKA |
+| 09 |EXT | 0B | 0D WEAKU | 0F WEAKT |
+
+| 10 WEAKD | 12 COMM | 14 SETA | 16 SETT |
+| 11 WEAKB | 13 | 15 | 17 |
+
+| 18 SETD | 1A SETB | 1C SETV | 1E WARNING|
+| 19 | 1B | 1D | 1F FN |
+*/
uint8_t * AddBSDSymEntry(uint8_t * buf, SYM * sym, int globflag)
{
chptr = buf; // Point to buffer for depositing longs
- D_long(strindx); // Deposit the symbol string index
+ if (sym->sname)
+ {
+ D_long(strindx); // Deposit the symbol string index
+ }
+ else
+ {
+ D_long(0); // Deposit special NULL string index
+ }
uint16_t w1 = sym->sattr; // Obtain symbol attributes
uint32_t z = 0; // Initialize resulting symbol flags
- if (w1 & EQUATED)
+ if (sym->stype == DBGSYM)
{
- z = 0x02000000; // Set equated flag
+ // Debug symbols hard-code the a.out symbol type in the st_type field
+ // and can include additional type-specific data in the a.out symbol
+ // "other" and "description" fields, both packed into this same dword.
+ z = sym->st_type << 24;
+ z |= sym->st_other << 16;
+ z |= sym->st_desc;
}
else
{
+ // Translate rmac symbol attributes to an a.out symbol type.
+ if (w1 & EQUATED)
+ {
+ z = 0x02000000; // Set equated flag
+ }
+
+ // If a symbol is both EQUd and flagged as TBD then we let the latter
+ // take precedence. Otherwise the linker will not even bother trying to
+ // relocate the address during link time.
+
switch (w1 & TDB)
{
case TEXT: z = 0x04000000; break; // Set TEXT segment flag
case DATA: z = 0x06000000; break; // Set DATA segment flag
case BSS : z = 0x08000000; break; // Set BSS segment flag
}
- }
- if (globflag)
- z |= 0x01000000; // Set global flag if requested
+ if (globflag)
+ z |= 0x01000000; // Set global flag if requested
+ }
D_long(z); // Deposit symbol attribute
z = sym->svalue; // Obtain symbol value
z += sect[DATA].sloc; // If BSS add DATA segment size
D_long(z); // Deposit symbol value
- strcpy(strtable + strindx, sym->sname);
- strindx += strlen(sym->sname) + 1; // Incr string index incl null terminate
+ if (sym->sname)
+ {
+ strcpy(strtable + strindx, sym->sname);
+ strindx += strlen(sym->sname) + 1; // Incr string index incl null terminate
+ }
buf += 12; // Increment buffer to next record
symsize += 12; // Increment symbol table size
return buf;
}
-
//
// Add entry to ELF symbol table; if `globflag' is 1, make the symbol global
//
register WORD w1 = sym->sattr;
- if (w1 & COMMON)
- {
- //w |= AL_EXTERN | AL_GLOBAL; // common symbol
- //w &= ~AL_BSS; // they're not BSS in Alcyon object files
- }
- else if (w1 & DEFINED)
+ if (w1 & DEFINED)
{
if (globflag) // Export the symbol
- st_info |= 16; //STB_GLOBAL (1<<4)
+ st_info |= 16; // STB_GLOBAL (1<<4)
}
else if (w1 & (GLOBAL | REFERENCED))
st_info |= 16;
D_byte(st_info);
D_byte(0); // st_other
- uint16_t st_shndx = 0xFFF1; // Assume absolute (equated) number
+ uint16_t st_shndx = SHN_ABS; // Assume absolute (equated) number
if (w1 & TEXT)
st_shndx = elfHdrNum[ES_TEXT];
st_shndx = elfHdrNum[ES_DATA];
else if (w1 & BSS)
st_shndx = elfHdrNum[ES_BSS];
- else if (globflag)
- st_shndx = 0; // Global, not absolute
+ else if (globflag && !(w1 & DEFINED) && (w1 & REFERENCED))
+ {
+ st_shndx = SHN_UNDEF;
+ } // If the symbol is global then probably we
+ // don't need to do anything (probably)
+ // since we set STB_GLOBAL in st_info above.
+ // Unless we need to set it to SHN_COMMON?
D_word(st_shndx);
return buf + 0x10;
}
-
//
// Helper function for ELF output
//
return 40;
}
-
//
// Deposit an entry in the Section Header string table
//
return strSize + 1;
}
-
//
// Deposit a symbol table entry in the ELF Symbol Table
//
return 16;
}
-
//
// Write an object file to the passed in file descriptor
// N.B.: Return value is ignored...
//
int WriteObject(int fd)
{
- LONG t; // Scratch long
LONG tds; // TEXT & DATA segment size
int i; // Temporary int
CHUNK * cp; // Chunk (for gather)
uint8_t * buf; // Scratch area
uint8_t * p; // Temporary ptr
LONG trsize, drsize; // Size of relocations
- long unused; // For supressing 'write' warnings
+ uint32_t unused; // For supressing 'write' warnings
if (verb_flag)
{
// Write requested object file...
if ((obj_format == BSD) || ((obj_format == ALCYON) && (prg_flag == 0)))
- {
+ {
+ ch_size = 0;
+
// Force BSD format (if it was ALCYON format)
obj_format = BSD;
printf("Total : %d bytes\n", sect[TEXT].sloc + sect[DATA].sloc + sect[BSS].sloc);
}
- sy_assign(NULL, NULL); // Assign index numbers to the symbols
+ AssignSymbolNos(NULL, NULL); // Assign index numbers to the symbols
tds = sect[TEXT].sloc + sect[DATA].sloc; // Get size of TEXT and DATA segment
- buf = malloc(0x800000); // Allocate 8MB object file image memory
+ buf = malloc(0x800000); // Allocate 8MB object file image memory
if (buf == NULL)
{
if (strtable == NULL)
{
+ free(buf);
error("cannot allocate string table memory (in BSD mode)");
return ERROR;
}
// Build object file header
chptr = buf; // Base of header (for D_foo macros)
+ ch_size = 0;
+ challoc = 0x800000;
D_long(0x00000107); // Magic number
D_long(sect[TEXT].sloc); // TEXT size
D_long(sect[DATA].sloc); // DATA size
// Point to start of symbol table
p = buf + BSDHDRSIZE + tds + trsize + drsize;
- sy_assign(p, AddBSDSymEntry); // Build symbol and string tables
+ AssignSymbolNos(p, AddBSDSymEntry); // Build symbol and string tables
chptr = buf + 0x10; // Point to sym table size hdr entry
D_long(symsize); // Write the symbol table size
}
else if (obj_format == ALCYON)
{
+ ch_size = 0;
+
if (verb_flag)
{
if (prg_flag)
// Assign index numbers to the symbols, get # of symbols (we assume
// that all symbols can potentially be extended, hence the x28)
- uint32_t symbolMaxSize = sy_assign(NULL, NULL) * 28;
+ // (To clarify: 28 bytes is the size of an extended symbol)
+ uint32_t symbolMaxSize = AssignSymbolNos(NULL, NULL) * 28;
// Alloc memory for header + text + data, symbol and relocation
// information construction.
// Build object file header just before the text+data image
chptr = buf; // -> base of header
+ ch_size = 0;
+ challoc = HDRSIZE + tds + symbolMaxSize;
D_word(0x601A); // 00 - magic number
D_long(sect[TEXT].sloc); // 02 - TEXT size
D_long(sect[DATA].sloc); // 06 - DATA size
// Construct symbol table and update the header entry, if necessary
if (prg_flag > 1)
{
- // sy_assign with AddSymEntry updates symsize (stays 0 otherwise)
- sy_assign(buf + HDRSIZE + tds, AddSymEntry);
+ // AssignSymbolNos with AddSymEntry updates symsize (stays 0 otherwise)
+ AssignSymbolNos(buf + HDRSIZE + tds, AddSymEntry);
chptr = buf + 0x0E; // Point to symbol table size entry
D_long(symsize);
+
+ if (verb_flag)
+ printf("Symbol table: %d bytes\n", symsize);
}
// Write out the header + text & data + symbol table (if any)
// If you want to make any sense out of this you'd better take a look
// at Executable and Linkable Format on Wikipedia.
chptr = buf;
+ ch_size = 0;
+ challoc = 0x600000;
D_long(0x7F454C46); // 00 - "<7F>ELF" Magic Number
D_byte(0x01); // 04 - 32 vs 64 (1 = 32, 2 = 64)
D_byte(0x02); // 05 - Endianness (1 = LE, 2 = BE)
extraSyms++;
}
- int numSymbols = sy_assign_ELF(buf + elfSize, AddELFSymEntry);
+ int numSymbols = AssignSymbolNosELF(buf + elfSize, AddELFSymEntry);
elfSize += numSymbols * 0x10;
// String table
// Just write the object file
m6502obj(fd);
}
+ else if (obj_format == C64PRG)
+ {
+ // Just write the object file
+ m6502c64(fd);
+ }
+ else if (obj_format == P56 || obj_format == LOD)
+ {
+ // Allocate 6MB object file image memory
+ uint8_t * buf = malloc(0x600000);
+
+ if (buf == NULL)
+ return error("cannot allocate object file memory (in P56/LOD mode)");
+
+ memset(buf, 0, 0x600000); // Clear allocated memory
+
+ // Iterate through DSP ram buffers
+ chptr = buf; // -> base of header
+ ch_size = 0;
+ challoc = 0x600000;
+
+ if (obj_format == LOD)
+ WriteLOD();
+ else
+ WriteP56();
+
+ // Write all the things \o/
+ unused = write(fd, buf, chptr - buf);
+
+ if (buf)
+ free(buf);
+ }
+ else if (obj_format == RAW)
+ {
+ if (!org68k_active && used_architectures & (!(M6502 | M56001P | M56001X | M56001Y | M56001L)))
+ return error("cannot output absolute binary without a starting address (.org or command line)");
+
+ if (used_architectures & M6502)
+ {
+ // Okay, this is not the best. But it'll have to do until we revamp things a bit with sections.
+ // Basically we assume that if raw output is requested and 6502 mode was switched on, nobody
+ // switched to other architectures. The combination doesn't make much sense anyway for now.
+ m6502raw(fd);
+ return 0;
+ }
+
+ // Alloc memory for text + data construction.
+ tds = sect[TEXT].sloc + sect[DATA].sloc;
+ buf = malloc(tds);
+ chptr = buf;
+
+ // Construct text and data segments; fixup relocatable longs;
+ // finally write the text + data
+
+ p = buf;
+ objImage = buf; // Set global object image pointer
+ for(i=TEXT; i<=DATA; i++)
+ {
+ for(cp=sect[i].sfcode; cp!=NULL; cp=cp->chnext)
+ {
+ memcpy(p, cp->chptr, cp->ch_size);
+ p += cp->ch_size;
+ }
+ }
+
+ if (MarkABSImage(buf, tds, sect[TEXT].sloc, TEXT) != OK) // Do TEXT relocation table
+ {
+ return ERROR;
+ }
+ if (MarkABSImage(buf, tds, sect[TEXT].sloc, DATA) != OK) // Do DATA relocation table
+ {
+ return ERROR;
+ }
+
+ // Write out the header + text & data + symbol table (if any)
+ unused = write(fd, buf, tds);
+
+ }
return 0;
}
+static void WriteLOD(void)
+{
+ D_printf("_START %s 0000 0000 0000 RMAC %01i.%01i.%01i\n\n", firstfname, MAJOR, MINOR, PATCH);
+
+ for(DSP_ORG * l=&dsp_orgmap[0]; l<dsp_currentorg; l++)
+ {
+ if (l->end != l->start)
+ {
+ switch (l->memtype)
+ {
+ case ORG_P: D_printf("_DATA P %.4X\n", l->orgadr); break;
+ case ORG_X: D_printf("_DATA X %.4X\n", l->orgadr); break;
+ case ORG_Y: D_printf("_DATA Y %.4X\n", l->orgadr); break;
+ case ORG_L: D_printf("_DATA L %.4X\n", l->orgadr); break;
+ default:
+ error("Internal error: unknown DSP56001 org'd section");
+ return;
+ }
+
+ CHUNK * cp = l->chunk;
+ uint8_t * p_chunk = l->start;
+ uint8_t * p_chunk_end = p_chunk;
+ uint32_t j = 0;
+
+ while (p_chunk_end != l->end)
+ {
+ if (l->end < (cp->chptr + cp->ch_size) && l->end > cp->chptr)
+ {
+ // If the end of the section is inside the current chunk, just dump everything and stop
+ p_chunk_end = l->end;
+ }
+ else
+ {
+ // If the end of the section is not inside the current chunk, just dump everything from the current chunk and move on to the next
+ p_chunk_end = cp->chptr + cp->ch_size;
+ }
+
+ uint32_t count = (uint32_t)(p_chunk_end - p_chunk);
+
+ for(uint32_t i=0; i<count; i+=3)
+ {
+ if ((j & 7) != 7)
+ {
+ D_printf("%.6X ", (((p_chunk[0] << 8) | p_chunk[1]) << 8) | p_chunk[2]);
+ }
+ else
+ {
+ D_printf("%.6X\n", (((p_chunk[0] << 8) | p_chunk[1]) << 8) | p_chunk[2]);
+ }
+
+ p_chunk += 3;
+ j++;
+ }
+
+ cp = cp->chnext; // Advance chunk
+
+ if (cp != NULL)
+ p_chunk = cp->chptr; // Set dump pointer to start of this chunk
+ }
+
+ if ((j & 7) != 0)
+ D_printf("\n");
+ }
+ }
+
+ // Dump the symbol table into the buf
+ DumpLODSymbols();
+
+ D_printf("\n_END %.4X\n", dsp_orgmap[0].orgadr);
+}
+
+static void WriteP56(void)
+{
+ for(DSP_ORG * l=&dsp_orgmap[0]; l<dsp_currentorg; l++)
+ {
+ if (l->end == l->start)
+ continue;
+
+ if ((l->memtype < ORG_P) || (l->memtype > ORG_L))
+ {
+ error("Internal error: unknown DSP56001 org'd section");
+ return;
+ }
+
+ CHUNK * cp = l->chunk;
+ uint8_t * p_chunk = l->start;
+ uint8_t * p_chunk_end = p_chunk;
+
+ // Memory type (P, X, Y or L)
+ D_dsp(l->memtype);
+
+ // Chunk start address (in DSP words)
+ D_dsp(l->orgadr);
+
+ // Chunk length (in DSP words)
+ // We'll fill this field after we write the chunk so we can calculate
+ // how long it is (so if the chunk is split into different CHUNKs we
+ // can deal with this during copy)
+ uint8_t * p_buf_len = chptr;
+ chptr += 3;
+
+ // The chunk itself
+ uint32_t chunk_size = 0;
+
+ while (p_chunk_end != l->end)
+ {
+ if (l->end < (cp->chptr + cp->ch_size) && l->end > cp->chptr)
+ {
+ // If the end of the section is inside the current chunk, just
+ // dump everything and stop
+ p_chunk_end = l->end;
+ }
+ else
+ {
+ // If the end of the section is not inside the current chunk,
+ // just dump everything from the current chunk and move on to
+ // the next
+ p_chunk_end = cp->chptr + cp->ch_size;
+ }
+
+ uint32_t current_chunk_size = p_chunk_end - p_chunk;
+ chunk_size += current_chunk_size;
+ memcpy(chptr, p_chunk, current_chunk_size);
+ chptr += current_chunk_size;
+
+ cp = cp->chnext; // Advance chunk
+
+ if (cp != NULL)
+ p_chunk = cp->chptr; // Set dump pointer to start of this chunk
+ }
+
+ // Now we can mark the chunk's length (DSP word size is 24-bits, so
+ // the byte count needs to be divided by 3)
+ SETBE24(p_buf_len, chunk_size / 3);
+ }
+}