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[emacs.git] / src / unexconvex.c
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1 /* Modified version of unexec for convex machines.
2 Note that the GNU project considers support for the peculiarities
3 of the Convex operating system a peripheral activity which should
4 not be allowed to divert effort from development of the GNU system.
5 Changes in this code will be installed when Convex system
6 maintainers send them in, but aside from that we don't plan to
7 think about it, or about whether other Emacs maintenance might
8 break it.
10 Copyright (C) 1985, 1986, 1988 Free Software Foundation, Inc.
12 This file is part of GNU Emacs.
14 GNU Emacs is free software; you can redistribute it and/or modify
15 it under the terms of the GNU General Public License as published by
16 the Free Software Foundation; either version 1, or (at your option)
17 any later version.
19 GNU Emacs is distributed in the hope that it will be useful,
20 but WITHOUT ANY WARRANTY; without even the implied warranty of
21 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
22 GNU General Public License for more details.
24 You should have received a copy of the GNU General Public License
25 along with GNU Emacs; see the file COPYING. If not, write to
26 the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */
29 /* modified for C-1 arch by jthomp@convex 871103 */
30 /* Corrected to support convex SOFF object file formats and thread specific
31 * regions. streepy@convex 890302
35 * unexec.c - Convert a running program into an a.out file.
37 * Author: Spencer W. Thomas
38 * Computer Science Dept.
39 * University of Utah
40 * Date: Tue Mar 2 1982
41 * Modified heavily since then.
43 * Synopsis:
44 * unexec (new_name, a_name, data_start, bss_start, entry_address)
45 * char *new_name, *a_name;
46 * unsigned data_start, bss_start, entry_address;
48 * Takes a snapshot of the program and makes an a.out format file in the
49 * file named by the string argument new_name.
50 * If a_name is non-NULL, the symbol table will be taken from the given file.
51 * On some machines, an existing a_name file is required.
53 * The boundaries within the a.out file may be adjusted with the data_start
54 * and bss_start arguments. Either or both may be given as 0 for defaults.
56 * Data_start gives the boundary between the text segment and the data
57 * segment of the program. The text segment can contain shared, read-only
58 * program code and literal data, while the data segment is always unshared
59 * and unprotected. Data_start gives the lowest unprotected address.
60 * The value you specify may be rounded down to a suitable boundary
61 * as required by the machine you are using.
63 * Specifying zero for data_start means the boundary between text and data
64 * should not be the same as when the program was loaded.
65 * If NO_REMAP is defined, the argument data_start is ignored and the
66 * segment boundaries are never changed.
68 * Bss_start indicates how much of the data segment is to be saved in the
69 * a.out file and restored when the program is executed. It gives the lowest
70 * unsaved address, and is rounded up to a page boundary. The default when 0
71 * is given assumes that the entire data segment is to be stored, including
72 * the previous data and bss as well as any additional storage allocated with
73 * break (2).
75 * The new file is set up to start at entry_address.
77 * If you make improvements I'd like to get them too.
78 * harpo!utah-cs!thomas, thomas@Utah-20
82 /* There are several compilation parameters affecting unexec:
84 * COFF
86 Define this if your system uses COFF for executables.
87 Otherwise we assume you use Berkeley format.
89 * NO_REMAP
91 Define this if you do not want to try to save Emacs's pure data areas
92 as part of the text segment.
94 Saving them as text is good because it allows users to share more.
96 However, on machines that locate the text area far from the data area,
97 the boundary cannot feasibly be moved. Such machines require
98 NO_REMAP.
100 Also, remapping can cause trouble with the built-in startup routine
101 /lib/crt0.o, which defines `environ' as an initialized variable.
102 Dumping `environ' as pure does not work! So, to use remapping,
103 you must write a startup routine for your machine in Emacs's crt0.c.
104 If NO_REMAP is defined, Emacs uses the system's crt0.o.
106 * SECTION_ALIGNMENT
108 Some machines that use COFF executables require that each section
109 start on a certain boundary *in the COFF file*. Such machines should
110 define SECTION_ALIGNMENT to a mask of the low-order bits that must be
111 zero on such a boundary. This mask is used to control padding between
112 segments in the COFF file.
114 If SECTION_ALIGNMENT is not defined, the segments are written
115 consecutively with no attempt at alignment. This is right for
116 unmodified system V.
118 * SEGMENT_MASK
120 Some machines require that the beginnings and ends of segments
121 *in core* be on certain boundaries. For most machines, a page
122 boundary is sufficient. That is the default. When a larger
123 boundary is needed, define SEGMENT_MASK to a mask of
124 the bits that must be zero on such a boundary.
126 * A_TEXT_OFFSET(HDR)
128 Some machines count the a.out header as part of the size of the text
129 segment (a_text); they may actually load the header into core as the
130 first data in the text segment. Some have additional padding between
131 the header and the real text of the program that is counted in a_text.
133 For these machines, define A_TEXT_OFFSET(HDR) to examine the header
134 structure HDR and return the number of bytes to add to `a_text'
135 before writing it (above and beyond the number of bytes of actual
136 program text). HDR's standard fields are already correct, except that
137 this adjustment to the `a_text' field has not yet been made;
138 thus, the amount of offset can depend on the data in the file.
140 * A_TEXT_SEEK(HDR)
142 If defined, this macro specifies the number of bytes to seek into the
143 a.out file before starting to write the text segment.a
145 * EXEC_MAGIC
147 For machines using COFF, this macro, if defined, is a value stored
148 into the magic number field of the output file.
150 * ADJUST_EXEC_HEADER
152 This macro can be used to generate statements to adjust or
153 initialize nonstandard fields in the file header
155 * ADDR_CORRECT(ADDR)
157 Macro to correct an int which is the bit pattern of a pointer to a byte
158 into an int which is the number of a byte.
160 This macro has a default definition which is usually right.
161 This default definition is a no-op on most machines (where a
162 pointer looks like an int) but not on all machines.
166 #include "config.h"
167 #define PERROR(file) report_error (file, new)
169 #include <a.out.h>
170 /* Define getpagesize () if the system does not.
171 Note that this may depend on symbols defined in a.out.h
173 #include "getpagesize.h"
175 #include <sys/types.h>
176 #include <stdio.h>
177 #include <sys/stat.h>
178 #include <errno.h>
180 extern char *start_of_text (); /* Start of text */
181 extern char *start_of_data (); /* Start of initialized data */
183 #include <machine/filehdr.h>
184 #include <machine/opthdr.h>
185 #include <machine/scnhdr.h>
186 #include <machine/pte.h>
188 static long block_copy_start; /* Old executable start point */
189 static struct filehdr f_hdr; /* File header */
190 static struct opthdr f_ohdr; /* Optional file header (a.out) */
191 long bias; /* Bias to add for growth */
192 #define SYMS_START block_copy_start
194 static long text_scnptr;
195 static long data_scnptr;
197 static int pagemask;
198 static int pagesz;
200 static
201 report_error (file, fd)
202 char *file;
203 int fd;
205 if (fd)
206 close (fd);
207 error ("Failure operating on %s", file);
210 #define ERROR0(msg) report_error_1 (new, msg, 0, 0); return -1
211 #define ERROR1(msg,x) report_error_1 (new, msg, x, 0); return -1
212 #define ERROR2(msg,x,y) report_error_1 (new, msg, x, y); return -1
214 static
215 report_error_1 (fd, msg, a1, a2)
216 int fd;
217 char *msg;
218 int a1, a2;
220 close (fd);
221 error (msg, a1, a2);
224 /* ****************************************************************
225 * unexec
227 * driving logic.
229 unexec (new_name, a_name, data_start, bss_start, entry_address)
230 char *new_name, *a_name;
231 unsigned data_start, bss_start, entry_address;
233 int new, a_out = -1;
235 if (a_name && (a_out = open (a_name, 0)) < 0) {
236 PERROR (a_name);
238 if ((new = creat (new_name, 0666)) < 0) {
239 PERROR (new_name);
242 if (make_hdr (new, a_out, data_start, bss_start, entry_address, a_name, new_name) < 0
243 || copy_text_and_data (new) < 0
244 || copy_sym (new, a_out, a_name, new_name) < 0 ) {
245 close (new);
246 return -1;
249 close (new);
250 if (a_out >= 0)
251 close (a_out);
252 mark_x (new_name);
253 return 0;
256 /* ****************************************************************
257 * make_hdr
259 * Make the header in the new a.out from the header in core.
260 * Modify the text and data sizes.
263 struct scnhdr *stbl; /* Table of all scnhdr's */
264 struct scnhdr *f_thdr; /* Text section header */
265 struct scnhdr *f_dhdr; /* Data section header */
266 struct scnhdr *f_tdhdr; /* Thread Data section header */
267 struct scnhdr *f_bhdr; /* Bss section header */
268 struct scnhdr *f_tbhdr; /* Thread Bss section header */
270 static int
271 make_hdr (new, a_out, data_start, bss_start, entry_address, a_name, new_name)
272 int new, a_out;
273 unsigned data_start, bss_start, entry_address;
274 char *a_name;
275 char *new_name;
277 register int scns;
278 unsigned int bss_end;
279 unsigned int eo_data; /* End of initialized data in new exec file */
280 int scntype; /* Section type */
281 int i; /* Var for sorting by vaddr */
282 struct scnhdr scntemp; /* For swapping entries in sort */
283 extern char *start_of_data();
285 pagemask = (pagesz = getpagesize()) - 1;
287 /* Adjust text/data boundary. */
288 if (!data_start)
289 data_start = (unsigned) start_of_data ();
291 data_start = data_start & ~pagemask; /* (Down) to page boundary. */
293 bss_end = (sbrk(0) + pagemask) & ~pagemask;
295 /* Adjust data/bss boundary. */
296 if (bss_start != 0) {
297 bss_start = (bss_start + pagemask) & ~pagemask;/* (Up) to page bdry. */
298 if (bss_start > bss_end) {
299 ERROR1 ("unexec: Specified bss_start (%x) is past end of program",
300 bss_start);
302 } else
303 bss_start = bss_end;
305 if (data_start > bss_start) { /* Can't have negative data size. */
306 ERROR2 ("unexec: data_start (%x) can't be greater than bss_start (%x)",
307 data_start, bss_start);
310 /* Salvage as much info from the existing file as possible */
311 if (a_out < 0) {
312 ERROR0 ("can't build a COFF file from scratch yet");
313 /*NOTREACHED*/
316 if (read (a_out, &f_hdr, sizeof (f_hdr)) != sizeof (f_hdr)) {
317 PERROR (a_name);
319 block_copy_start += sizeof (f_hdr);
320 if (f_hdr.h_opthdr > 0) {
321 if (read (a_out, &f_ohdr, sizeof (f_ohdr)) != sizeof (f_ohdr)) {
322 PERROR (a_name);
324 block_copy_start += sizeof (f_ohdr);
327 /* Allocate room for scn headers */
328 stbl = (struct scnhdr *)malloc( sizeof(struct scnhdr) * f_hdr.h_nscns );
329 if( stbl == NULL ) {
330 ERROR0( "unexec: malloc of stbl failed" );
333 f_tdhdr = f_tbhdr = NULL;
335 /* Loop through section headers, copying them in */
336 for (scns = 0; scns < f_hdr.h_nscns; scns++) {
338 if( read( a_out, &stbl[scns], sizeof(*stbl)) != sizeof(*stbl)) {
339 PERROR (a_name);
342 scntype = stbl[scns].s_flags & S_TYPMASK; /* What type of section */
344 if( stbl[scns].s_scnptr > 0L) {
345 if( block_copy_start < stbl[scns].s_scnptr + stbl[scns].s_size )
346 block_copy_start = stbl[scns].s_scnptr + stbl[scns].s_size;
349 if( scntype == S_TEXT) {
350 f_thdr = &stbl[scns];
351 } else if( scntype == S_DATA) {
352 f_dhdr = &stbl[scns];
353 #ifdef S_TDATA
354 } else if( scntype == S_TDATA ) {
355 f_tdhdr = &stbl[scns];
356 } else if( scntype == S_TBSS ) {
357 f_tbhdr = &stbl[scns];
358 #endif /* S_TDATA (thread stuff) */
360 } else if( scntype == S_BSS) {
361 f_bhdr = &stbl[scns];
366 /* We will now convert TEXT and DATA into TEXT, BSS into DATA, and leave
367 * all thread stuff alone.
370 /* Now we alter the contents of all the f_*hdr variables
371 to correspond to what we want to dump. */
373 f_thdr->s_vaddr = (long) start_of_text ();
374 f_thdr->s_size = data_start - f_thdr->s_vaddr;
375 f_thdr->s_scnptr = pagesz;
376 f_thdr->s_relptr = 0;
377 f_thdr->s_nrel = 0;
379 eo_data = f_thdr->s_scnptr + f_thdr->s_size;
381 if( f_tdhdr ) { /* Process thread data */
383 f_tdhdr->s_vaddr = data_start;
384 f_tdhdr->s_size += f_dhdr->s_size - (data_start - f_dhdr->s_vaddr);
385 f_tdhdr->s_scnptr = eo_data;
386 f_tdhdr->s_relptr = 0;
387 f_tdhdr->s_nrel = 0;
389 eo_data += f_tdhdr->s_size;
391 /* And now for DATA */
393 f_dhdr->s_vaddr = f_bhdr->s_vaddr; /* Take BSS start address */
394 f_dhdr->s_size = bss_end - f_bhdr->s_vaddr;
395 f_dhdr->s_scnptr = eo_data;
396 f_dhdr->s_relptr = 0;
397 f_dhdr->s_nrel = 0;
399 eo_data += f_dhdr->s_size;
401 } else {
403 f_dhdr->s_vaddr = data_start;
404 f_dhdr->s_size = bss_start - data_start;
405 f_dhdr->s_scnptr = eo_data;
406 f_dhdr->s_relptr = 0;
407 f_dhdr->s_nrel = 0;
409 eo_data += f_dhdr->s_size;
413 f_bhdr->s_vaddr = bss_start;
414 f_bhdr->s_size = bss_end - bss_start + pagesz /* fudge */;
415 f_bhdr->s_scnptr = 0;
416 f_bhdr->s_relptr = 0;
417 f_bhdr->s_nrel = 0;
419 text_scnptr = f_thdr->s_scnptr;
420 data_scnptr = f_dhdr->s_scnptr;
421 bias = eo_data - block_copy_start;
423 if (f_ohdr.o_symptr > 0L) {
424 f_ohdr.o_symptr += bias;
427 if (f_hdr.h_strptr > 0) {
428 f_hdr.h_strptr += bias;
431 if (write (new, &f_hdr, sizeof (f_hdr)) != sizeof (f_hdr)) {
432 PERROR (new_name);
435 if (write (new, &f_ohdr, sizeof (f_ohdr)) != sizeof (f_ohdr)) {
436 PERROR (new_name);
439 for( scns = 0; scns < f_hdr.h_nscns; scns++ ) {
441 /* This is a cheesey little loop to write out the section headers
442 * in order of increasing virtual address. Dull but effective.
445 for( i = scns+1; i < f_hdr.h_nscns; i++ ) {
446 if( stbl[i].s_vaddr < stbl[scns].s_vaddr ) { /* Swap */
447 scntemp = stbl[i];
448 stbl[i] = stbl[scns];
449 stbl[scns] = scntemp;
455 for( scns = 0; scns < f_hdr.h_nscns; scns++ ) {
457 if( write( new, &stbl[scns], sizeof(*stbl)) != sizeof(*stbl)) {
458 PERROR (new_name);
463 return (0);
467 /* ****************************************************************
468 * copy_text_and_data
470 * Copy the text and data segments from memory to the new a.out
472 static int
473 copy_text_and_data (new)
474 int new;
476 register int scns;
478 for( scns = 0; scns < f_hdr.h_nscns; scns++ )
479 write_segment( new, &stbl[scns] );
481 return 0;
484 write_segment( new, sptr )
485 int new;
486 struct scnhdr *sptr;
488 register char *ptr, *end;
489 register int nwrite, ret;
490 char buf[80];
491 extern int errno;
492 char zeros[128];
494 if( sptr->s_scnptr == 0 )
495 return; /* Nothing to do */
497 if( lseek( new, (long) sptr->s_scnptr, 0 ) == -1 )
498 PERROR( "unexecing" );
500 bzero (zeros, sizeof zeros);
502 ptr = (char *) sptr->s_vaddr;
503 end = ptr + sptr->s_size;
505 while( ptr < end ) {
507 /* distance to next multiple of 128. */
508 nwrite = (((int) ptr + 128) & -128) - (int) ptr;
509 /* But not beyond specified end. */
510 if (nwrite > end - ptr) nwrite = end - ptr;
511 ret = write (new, ptr, nwrite);
512 /* If write gets a page fault, it means we reached
513 a gap between the old text segment and the old data segment.
514 This gap has probably been remapped into part of the text segment.
515 So write zeros for it. */
516 if (ret == -1 && errno == EFAULT)
517 write (new, zeros, nwrite);
518 else if (nwrite != ret) {
519 sprintf (buf,
520 "unexec write failure: addr 0x%x, fileno %d, size 0x%x, wrote 0x%x, errno %d",
521 ptr, new, nwrite, ret, errno);
522 PERROR (buf);
524 ptr += nwrite;
528 /* ****************************************************************
529 * copy_sym
531 * Copy the relocation information and symbol table from the a.out to the new
533 static int
534 copy_sym (new, a_out, a_name, new_name)
535 int new, a_out;
536 char *a_name, *new_name;
538 char page[1024];
539 int n;
541 if (a_out < 0)
542 return 0;
544 if (SYMS_START == 0L)
545 return 0;
547 lseek (a_out, SYMS_START, 0); /* Position a.out to symtab. */
548 lseek( new, (long)f_ohdr.o_symptr, 0 );
550 while ((n = read (a_out, page, sizeof page)) > 0) {
551 if (write (new, page, n) != n) {
552 PERROR (new_name);
555 if (n < 0) {
556 PERROR (a_name);
558 return 0;
561 /* ****************************************************************
562 * mark_x
564 * After succesfully building the new a.out, mark it executable
566 static
567 mark_x (name)
568 char *name;
570 struct stat sbuf;
571 int um;
572 int new = 0; /* for PERROR */
574 um = umask (777);
575 umask (um);
576 if (stat (name, &sbuf) == -1) {
577 PERROR (name);
579 sbuf.st_mode |= 0111 & ~um;
580 if (chmod (name, sbuf.st_mode) == -1)
581 PERROR (name);
584 /* Find the first pty letter. This is usually 'p', as in ptyp0, but
585 is sometimes configured down to 'm', 'n', or 'o' for some reason. */
587 first_pty_letter ()
589 struct stat buf;
590 char pty_name[16];
591 char c;
593 for (c = 'o'; c >= 'a'; c--)
595 sprintf (pty_name, "/dev/pty%c0", c);
596 if (stat (pty_name, &buf) < 0)
597 return c + 1;
599 return 'a';