#ifndef lint static char rcsid[] = "$Header$"; #endif #ifdef SYMDBUG #include #include #endif SYMDBUG #include "../../h/arch.h" #include "../../h/out.h" #include "../../h/ranlib.h" #include "const.h" #include "assert.h" #include "memory.h" #include "scan.h" #define READ 0 #define IND_EMIT(x) (IND_CHAR(x) + (ind_t)align((x).oh_nchar)) #define IND_RELO(x) (IND_EMIT(x) + (x).oh_nsect * sizeof(ind_t)) #ifdef SYMDBUG #define IND_DBUG(x) (IND_RELO(x) + sizeof(ind_t)) #endif SYMDBUG extern long lseek(); extern bool incore; extern int infile; extern int passnumber; char *archname; /* Name of archive, if reading from archive. */ char *modulname; /* Name of object module. */ long position; /* Byte offset within cuurent input file. */ #ifdef SYMDBUG long objectsize; #endif SYMDBUG static long align(); static char *modulbase; static long modulsize(); static scan_modul(); static bool all_alloc(); static bool direct_alloc(); static bool indirect_alloc(); static bool putemitindex(); static bool putreloindex(); #ifdef SYMDBUG static bool putdbugindex(); #endif SYMDBUG static get_indirect(); static read_modul(); /* * Open the file with name `filename' (if necessary) and examine the first * few bytes to see if it's a plain file or an archive. * In case of a plain file, the file pointer is repositioned after the * examination. Otherwise it is at the beginning of the table of contents. */ int getfile(filename) char *filename; { struct ar_hdr archive_header; ushort magic_number; #ifdef SYMDBUG struct stat statbuf; extern int fstat(); #endif SYMDBUG extern ushort getushort(); archname = (char *)0; modulname = (char *)0; if (passnumber == FIRST || !incore) { if ((infile = open(filename, READ)) < 0) fatal("can't read %s", filename); magic_number = getushort(); } else { modulbase = modulptr((ind_t)0); magic_number = *(ushort *)modulbase; } switch (magic_number) { case O_MAGIC: #ifdef SYMDBUG if (passnumber == FIRST || !incore) { if (fstat(infile, &statbuf) < 0) fatal("cannot stat"); objectsize = statbuf.st_size; } #endif SYMDBUG position = (long)0; seek((long)0); modulname = filename; return PLAIN; case ARMAG: warning("Using out-of-date archive %s",filename) ; case AALMAG: archname = filename; if (passnumber == FIRST) { read_arhdr(&archive_header); if (strcmp(archive_header.ar_name, SYMDEF)) fatal("no table of contents"); } else if (incore) { modulbase += sizeof(ushort); core_position += sizeof(ushort); } return ARCHIVE; default: fatal("wrong magic number"); } /* NOTREACHED */ } /* ARGSUSED */ closefile(filename) char *filename; { if (passnumber == FIRST || !incore) close(infile); } get_archive_header(archive_header) register struct ar_hdr *archive_header; { if (passnumber == FIRST || !incore) { read_arhdr(archive_header); } else { /* Copy structs. */ *archive_header = *(struct ar_hdr *)modulbase; modulbase += sizeof(struct ar_hdr); core_position += sizeof(struct ar_hdr); } #ifdef SYMDBUG objectsize = archive_header.ar_size; #endif SYMDBUG } get_modul() { if (passnumber == FIRST) { scan_modul(); } else if (!incore) { read_modul(); } } /* * Read module from the current file. If it doesn't fit into core, the strategy * to keep everything in core is abandoned, but we will always put the header, * the section table, and the name and string table into core. */ static scan_modul() { bool space; struct outhead *head; struct outsect *sect; space = all_alloc(); head = (struct outhead *)modulptr(IND_HEAD); if (space) { sect = (struct outsect *)modulptr(IND_SECT(*head)); get_indirect(head, sect); } else { lseek(infile, OFF_NAME(*head) - OFF_EMIT(*head), 1); } read_name((struct outname *)modulptr(IND_NAME(*head)), head->oh_nname); read_char((char *)modulptr(IND_CHAR(*head)), head->oh_nchar); #ifdef SYMDBUG if (space) { get_dbug(*(ind_t *)modulptr(IND_DBUG(*head)), ojectsize - OFF_DBUG(*head) ); } #endif SYMDBUG } /* * Allocate space for and read in the header and section table. * First get the header. With this we can determine what to allocate * for the rest of the module, and with the rest we can determine what * to allocate for the section contents. * If possible, allocate space for the rest of the module. Return whether * this was possible. */ static bool all_alloc() { struct outhead head; extern ind_t hard_alloc(); if (hard_alloc(ALLOMODL, (long)sizeof(struct outhead)) == BADOFF) fatal("no space for module header"); read_head((struct outhead *)modulptr(IND_HEAD)); /* * Copy the header because we need it so often. */ head = *(struct outhead *)modulptr(IND_HEAD); return direct_alloc(&head) && indirect_alloc(&head); } /* * Allocate space for the rest of the direct bytes. * First allocate the section table and read it in, then allocate the rest * and return whether this succeeded. */ static bool direct_alloc(head) struct outhead *head; { ind_t sectindex = IND_SECT(*head); ushort nsect = head->oh_nsect; long size, rest; extern ind_t hard_alloc(); extern ind_t alloc(); #ifdef SYMDBUG rest = nsect * sizeof(ind_t) + sizeof(ind_t) + sizeof(ind_t); #else SYMDBUG rest = nsect * sizeof(ind_t) + sizeof(ind_t); #endif SYMDBUG /* * We already allocated space for the header, we now need * the section, name an string table. */ size = modulsize(head) - sizeof(struct outhead) - rest; if (hard_alloc(ALLOMODL, size) == BADOFF) fatal("no space for module"); read_sect((struct outsect *)modulptr(sectindex), nsect); return incore && alloc(ALLOMODL, rest) != BADOFF; } /* * Allocate space for the indirectly accessed pieces: the section contents and * the relocation table, and put their indices in the right place. */ static bool indirect_alloc(head) struct outhead *head; { register int allopiece; ushort nsect = head->oh_nsect; ushort nrelo = head->oh_nrelo; ind_t sectindex = IND_SECT(*head); ind_t emitoff = IND_EMIT(*head); ind_t relooff = IND_RELO(*head); #ifdef SYMDBUG ind_t dbugoff = IND_DBUG(*head); extern long objectsize; long dbugsize = objectsize - OFF_DBUG(*head); #endif SYMDBUG assert(incore); for (allopiece = ALLOEMIT; allopiece < ALLOEMIT + nsect; allopiece++) { if (!putemitindex(sectindex, emitoff, allopiece)) return FALSE; sectindex += sizeof(struct outsect); emitoff += sizeof(ind_t); } #ifdef SYMDBUG return putreloindex(relooff, (long)nrelo * sizeof(struct outrelo)) && putdbugindex(dbugoff, dbugsize); #else SYMDBUG return putreloindex(relooff, (long)nrelo * sizeof(struct outrelo)); #endif SYMDBUG } /* * Allocate space for the contents of the section of which the table entry is * at offset `sectindex'. Put the offset of the allocated piece at offset * `emitoff'. */ static bool putemitindex(sectindex, emitoff, allopiece) ind_t sectindex; ind_t emitoff; int allopiece; { long flen; ind_t emitindex; extern ind_t alloc(); flen = ((struct outsect *)modulptr(sectindex))->os_flen; if ((emitindex = alloc(allopiece, flen)) != BADOFF) { *(ind_t *)modulptr(emitoff) = emitindex; return TRUE; } return FALSE; } /* * Allocate space for a relocation table with `nrelobytes' bytes, and put the * offset at `relooff'. */ static bool putreloindex(relooff, nrelobytes) ind_t relooff; long nrelobytes; { ind_t reloindex; extern ind_t alloc(); if ((reloindex = alloc(ALLORELO, nrelobytes)) != BADOFF) { *(ind_t *)modulptr(relooff) = reloindex; return TRUE; } return FALSE; } #ifdef SYMDBUG /* * Allocate space for debugging information and put the offset at `dbugoff'. */ static bool putdbugindex(dbugoff, ndbugbytes) ind_t relooff; long ndbugbytes; { ind_t dbugindex; extern ind_t alloc(); if ((dbugindex = alloc(ALLORELO, ndbugbytes)) != BADOFF) { *(ind_t *)modulptr(dbugoff) = dbugindex; return TRUE; } return FALSE; } #endif SYMDBUG /* * Compute addresses and read in. Remember that the contents of the sections * and also the relocation table are accessed indirectly. */ static get_indirect(head, sect) register struct outhead *head; register struct outsect *sect; { register ind_t *emitindex; register int nsect; register int piece; ind_t *reloindex; emitindex = (ind_t *)modulptr(IND_EMIT(*head)); nsect = head->oh_nsect; piece = ALLOEMIT; while (nsect--) { read_emit(address(piece, *emitindex), sect->os_flen); piece++; emitindex++; sect++; } reloindex = (ind_t *)modulptr(IND_RELO(*head)); read_relo((struct outrelo *)address(ALLORELO, *reloindex), head->oh_nrelo ); } /* * Set the file pointer at `pos'. */ seek(pos) long pos; { if (passnumber == FIRST || !incore) lseek(infile, pos, 0); } /* * A file pointer is advanced automatically when reading, a char pointer * is not. That's why we do it here. If we don't keep everything in core, * we give the space allocated for a module back. */ skip_modul(head) struct outhead *head; { register ind_t skip = modulsize(head); if (incore) { core_position += skip; if (passnumber == SECOND) modulbase += skip; } else { dealloc(ALLOMODL); core_position = (ind_t)0; } } /* * Read in what we need in pass 2, because we couldn't keep it in core. */ static read_modul() { struct outhead *head; struct outsect *sects; struct outname *names; char *chars; ind_t sectindex, nameindex, charindex; ushort nsect, nname; long size; long nchar; long skip; extern ind_t hard_alloc(); assert(passnumber == SECOND); assert(!incore); if (hard_alloc(ALLOMODL, (long)sizeof(struct outhead)) == BADOFF) fatal("no space for module header"); head = (struct outhead *)modulptr(IND_HEAD); read_head(head); nsect = head->oh_nsect; sectindex = IND_SECT(*head); nname = head->oh_nname; nameindex = IND_NAME(*head); nchar = head->oh_nchar; charindex = IND_CHAR(*head); skip = OFF_NAME(*head) - OFF_EMIT(*head); #ifdef SYMDBUG size = modulsize(head) - (nsect * sizeof(ind_t) + 2 * sizeof(ind_t)); #else SYMDBUG size = modulsize(head) - (nsect * sizeof(ind_t) + sizeof(ind_t)); #endif SYMDBUG if (hard_alloc(ALLOMODL, size) == BADOFF) fatal("no space for module"); sects = (struct outsect *)modulptr(sectindex); names = (struct outname *)modulptr(nameindex); chars = modulptr(charindex); read_sect(sects, nsect); lseek(infile, skip, 1); read_name(names, nname); read_char(chars, nchar); } /* * Align `size' to a multiple of the size of a double. * This is assumed to be a power of 2. */ static long align(size) register long size; { size += sizeof(double) - 1; return size - (size & (sizeof(double) - 1)); } /* * Compute how many DIRECT bytes must be allocated for a module of which the * header is pointed to by `head': * 0. the header, * 1. the section table, * 2. the name table, * 3. the string table, * 4. for each section the offset of its contents, * 5. the offset of the relocation table. #ifdef SYMDBUG * 6. the offset of the debugging information. #endif SYMDBUG */ static long modulsize(head) register struct outhead *head; { return sizeof(struct outhead) + /* 0 */ head->oh_nsect * sizeof(struct outsect) + /* 1 */ head->oh_nname * sizeof(struct outname) + /* 2 */ align(head->oh_nchar) + /* 3 */ head->oh_nsect * sizeof(ind_t) + /* 4 */ #ifdef SYMDBUG sizeof(ind_t) + /* 5 */ sizeof(ind_t); /* 6 */ #else SYMDBUG sizeof(ind_t); /* 5 */ #endif SYMDBUG } /* ------------------------------------------------------------------------- */ /* * Walk through the relocation table of the current module. We must either walk * through core or through file. Startrelo() should be called first. */ static struct outrelo *walkrelo; startrelo(head) struct outhead *head; { ind_t reloindex; if (incore) { reloindex = *(ind_t *)(modulbase + IND_RELO(*head)); walkrelo = (struct outrelo *)address(ALLORELO, reloindex); } else lseek(infile, position + OFF_RELO(*head), 0); } struct outrelo * nextrelo() { static struct outrelo relobuf; if (incore) return walkrelo++; read_relo(&relobuf, (ushort)1); return &relobuf; } /* ------------------------------------------------------------------------- */ /* * Get the section contents in core of which the describing struct has index * `sectindex'. `Head' points to the header of the module. */ char * getemit(head, sects, sectindex) struct outhead *head; struct outsect *sects; int sectindex; { char *ret; ind_t off; extern char *core_alloc(); if (!incore) { ret = core_alloc(ALLOMODL, sects[sectindex].os_flen); if (ret == (char *)0) fatal("no space for section contents"); lseek(infile, position + sects[sectindex].os_foff, 0); read_emit(ret, sects[sectindex].os_flen); return ret; } /* * We have an offset in the contents of the final output * "file" where normally the contents would be. */ off = *((ind_t *)(modulbase + IND_EMIT(*head)) + sectindex); return address(ALLOEMIT + sectindex, off); }