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[prefix] Remove .bImage in favor of .lkrn

The .lkrn prefix allows gPXE to be loaded as a Linux bzImage.  The
bImage prefix was carried over from legacy Etherboot and does not build.
This patch removes the .bImage prefix, use .lkrn instead.

Signed-off-by: Stefan Hajnoczi <stefanha@gmail.com>
Signed-off-by: Marty Connor <mdc@etherboot.org>
tags/v1.0.0
Stefan Hajnoczi 14 gadus atpakaļ
vecāks
revīzija
d3b9c3f3d0
2 mainītis faili ar 0 papildinājumiem un 612 dzēšanām
  1. 0
    1
      src/arch/i386/Makefile.pcbios
  2. 0
    611
      src/arch/i386/prefix/bImageprefix.S

+ 0
- 1
src/arch/i386/Makefile.pcbios Parādīt failu

@@ -21,7 +21,6 @@ MEDIA		+= elfd
21 21
 MEDIA		+= lmelf
22 22
 MEDIA		+= lmelfd
23 23
 MEDIA		+= lkrn
24
-MEDIA		+= bImage
25 24
 MEDIA		+= dsk
26 25
 MEDIA		+= nbi
27 26
 MEDIA		+= hd

+ 0
- 611
src/arch/i386/prefix/bImageprefix.S Parādīt failu

@@ -1,611 +0,0 @@
1
-/*
2
-	Copyright (C) 2000, Entity Cyber, Inc.
3
-
4
-	Authors: Gary Byers (gb@thinguin.org)
5
-		 Marty Connor (mdc@thinguin.org)
6
-		 Eric Biederman (ebiederman@lnxi.com)
7
-
8
-	This code also derives a lot from arch/i386/boot/setup.S in
9
-	the linux kernel.
10
-
11
-	This software may be used and distributed according to the terms
12
-	of the GNU Public License (GPL), incorporated herein by reference.
13
-
14
-	Description:	
15
-
16
-	This is just a little bit of code and data that can get prepended
17
-	to an Etherboot ROM image in order to allow LILO to load the
18
-	result as if it were a Linux kernel image.
19
-
20
-	A real Linux kernel image consists of a one-sector boot loader
21
-	(to load the image from a floppy disk), followed a few sectors
22
-	of setup code, followed by the kernel code itself.  There's
23
-	a table in the first sector (starting at offset 497) that indicates
24
-	how many sectors of setup code follow the first sector and which
25
-	contains some other parameters that aren't interesting in this
26
-	case.
27
-
28
-	When LILO loads the sectors that comprise a kernel image, it doesn't
29
-	execute the code in the first sector (since that code would try to
30
-	load the image from a floppy disk.)  The code in the first sector
31
-	below doesn't expect to get executed (and prints an error message
32
-	if it ever -is- executed.)  LILO's only interested in knowing the
33
-	number of setup sectors advertised in the table (at offset 497 in
34
-	the first sector.)
35
-
36
-	Etherboot doesn't require much in the way of setup code.
37
-	Historically, the Linux kernel required at least 4 sectors of
38
-	setup code.  Current versions of LILO look at the byte at
39
-	offset 497 in the first sector to indicate how many sectors
40
-	of setup code are contained in the image.
41
-
42
-	The setup code that is present here does a lot of things
43
-	exactly the way the linux kernel does them instead of in
44
-	ways more typical of etherboot.  Generally this is so
45
-	the code can be strongly compatible with the linux kernel.
46
-	In addition the general etherboot technique of enabling the a20
47
-	after we switch into protected mode does not work if etherboot
48
-	is being loaded at 1MB.
49
-*/
50
-
51
-	.equ	CR0_PE,1
52
-
53
-#ifdef	GAS291
54
-#define DATA32 data32;
55
-#define ADDR32 addr32;
56
-#define	LJMPI(x)	ljmp	x
57
-#else
58
-#define DATA32 data32
59
-#define ADDR32 addr32
60
-/* newer GAS295 require #define	LJMPI(x)	ljmp	*x */
61
-#define	LJMPI(x)	ljmp	x
62
-#endif
63
-
64
-/* Simple and small GDT entries for booting only */
65
-#define GDT_ENTRY_BOOT_CS	2
66
-#define GDT_ENTRY_BOOT_DS	(GDT_ENTRY_BOOT_CS + 1)
67
-#define __BOOT_CS	(GDT_ENTRY_BOOT_CS * 8)
68
-#define __BOOT_DS	(GDT_ENTRY_BOOT_DS * 8)
69
-
70
-
71
-#define	SETUPSECS 4		/* Minimal nr of setup-sectors */
72
-#define PREFIXSIZE ((SETUPSECS+1)*512)
73
-#define PREFIXPGH (PREFIXSIZE / 16 )
74
-#define	BOOTSEG  0x07C0		/* original address of boot-sector */
75
-#define	INITSEG  0x9000		/* we move boot here - out of the way */
76
-#define	SETUPSEG 0x9020		/* setup starts here */
77
-#define SYSSEG   0x1000		/* system loaded at 0x10000 (65536). */
78
-
79
-#define DELTA_INITSEG  (SETUPSEG - INITSEG) /* 0x0020 */
80
-	
81
-/* Signature words to ensure LILO loaded us right */
82
-#define SIG1	0xAA55
83
-#define SIG2	0x5A5A
84
-
85
-	.text
86
-	.code16
87
-	.arch i386
88
-	.org	0
89
-	.section ".prefix", "ax", @progbits
90
-_prefix:
91
-
92
-/* 
93
-	This is a minimal boot sector.	If anyone tries to execute it (e.g., if
94
-	a .lkrn file is dd'ed to a floppy), print an error message. 
95
-*/
96
-
97
-bootsector: 
98
-	jmp	$BOOTSEG, $go - _prefix	/* reload cs:ip to match relocation addr */
99
-go: 
100
-	movw	$0x2000, %di		/*  0x2000 is arbitrary value >= length
101
-					    of bootsect + room for stack */
102
-
103
-	movw	$BOOTSEG, %ax
104
-	movw	%ax,%ds
105
-	movw	%ax,%es
106
-
107
-	cli
108
-	movw	%ax, %ss		/* put stack at BOOTSEG:0x2000. */
109
-	movw	%di,%sp
110
-	sti
111
-
112
-	movw	$why_end-why, %cx
113
-	movw	$why - _prefix, %si
114
-
115
-	movw	$0x0007, %bx		/* page 0, attribute 7 (normal) */
116
-	movb	$0x0e, %ah		/* write char, tty mode */
117
-prloop: 
118
-	lodsb
119
-	int	$0x10
120
-	loop	prloop
121
-freeze: jmp	freeze
122
-
123
-why:	.ascii	"This image cannot be loaded from a floppy disk.\r\n"
124
-why_end: 
125
-
126
-
127
-	.org	497
128
-setup_sects: 
129
-	.byte	SETUPSECS
130
-root_flags: 
131
-	.word	0
132
-syssize: 
133
-	.word	_verbatim_size_pgh - PREFIXPGH
134
-swap_dev: 
135
-	.word	0
136
-ram_size: 
137
-	.word	0
138
-vid_mode: 
139
-	.word	0
140
-root_dev: 
141
-	.word	0
142
-boot_flag: 
143
-	.word	0xAA55
144
-
145
-/*
146
-	We're now at the beginning of the second sector of the image -
147
-	where the setup code goes.
148
-
149
-	We don't need to do too much setup for Etherboot.
150
-
151
-	This code gets loaded at SETUPSEG:0.  It wants to start
152
-	executing the Etherboot image that's loaded at SYSSEG:0 and
153
-	whose entry point is SYSSEG:0.
154
-*/
155
-setup_code:
156
-	jmp	trampoline
157
-# This is the setup header, and it must start at %cs:2 (old 0x9020:2)
158
-
159
-		.ascii	"HdrS"		# header signature
160
-		.word	0x0203		# header version number (>= 0x0105)
161
-					# or else old loadlin-1.5 will fail)
162
-realmode_swtch:	.word	0, 0		# default_switch, SETUPSEG
163
-start_sys_seg:	.word	SYSSEG		# low load segment (obsolete)
164
-		.word	kernel_version - setup_code
165
-					# pointing to kernel version string
166
-					# above section of header is compatible
167
-					# with loadlin-1.5 (header v1.5). Don't
168
-					# change it.
169
-
170
-type_of_loader:	.byte	0		# = 0, old one (LILO, Loadlin,
171
-					#      Bootlin, SYSLX, bootsect...)
172
-					# See Documentation/i386/boot.txt for
173
-					# assigned ids
174
-	
175
-# flags, unused bits must be zero (RFU) bit within loadflags
176
-loadflags:
177
-LOADED_HIGH	= 1			# If set, the kernel is loaded high
178
-CAN_USE_HEAP	= 0x80			# If set, the loader also has set
179
-					# heap_end_ptr to tell how much
180
-					# space behind setup.S can be used for
181
-					# heap purposes.
182
-					# Only the loader knows what is free
183
-		.byte	LOADED_HIGH
184
-
185
-setup_move_size: .word  0x8000		# size to move, when setup is not
186
-					# loaded at 0x90000. We will move setup 
187
-					# to 0x90000 then just before jumping
188
-					# into the kernel. However, only the
189
-					# loader knows how much data behind
190
-					# us also needs to be loaded.
191
-
192
-code32_start:				# here loaders can put a different
193
-					# start address for 32-bit code.
194
-		.long	0x100000	# 0x100000 = default for big kernel
195
-
196
-ramdisk_image:	.long	0		# address of loaded ramdisk image
197
-					# Here the loader puts the 32-bit
198
-					# address where it loaded the image.
199
-					# This only will be read by the kernel.
200
-
201
-ramdisk_size:	.long	0		# its size in bytes
202
-
203
-bootsect_kludge:
204
-		.long	0		# obsolete
205
-
206
-heap_end_ptr:	.word	0		# (Header version 0x0201 or later)
207
-					# space from here (exclusive) down to
208
-					# end of setup code can be used by setup
209
-					# for local heap purposes.
210
-
211
-pad1:		.word	0
212
-cmd_line_ptr:	.long 0			# (Header version 0x0202 or later)
213
-					# If nonzero, a 32-bit pointer
214
-					# to the kernel command line.
215
-					# The command line should be
216
-					# located between the start of
217
-					# setup and the end of low
218
-					# memory (0xa0000), or it may
219
-					# get overwritten before it
220
-					# gets read.  If this field is
221
-					# used, there is no longer
222
-					# anything magical about the
223
-					# 0x90000 segment; the setup
224
-					# can be located anywhere in
225
-					# low memory 0x10000 or higher.
226
-
227
-ramdisk_max:	.long 0			# (Header version 0x0203 or later)
228
-					# The highest safe address for
229
-					# the contents of an initrd
230
-
231
-trampoline:	call	start_of_setup
232
-trampoline_end:
233
-		.space	1024
234
-# End of setup header #####################################################
235
-
236
-start_of_setup:
237
-# Set %ds = %cs, we know that SETUPSEG = %cs at this point
238
-	movw	%cs, %ax		# aka SETUPSEG
239
-	movw	%ax, %ds
240
-# Check signature at end of setup
241
-	cmpw	$SIG1, (setup_sig1 - setup_code)
242
-	jne	bad_sig
243
-
244
-	cmpw	$SIG2, (setup_sig2 - setup_code)
245
-	jne	bad_sig
246
-
247
-	jmp	good_sig1
248
-
249
-# Routine to print asciiz string at ds:si
250
-prtstr:
251
-	lodsb
252
-	andb	%al, %al
253
-	jz	fin
254
-
255
-	call	prtchr
256
-	jmp	prtstr
257
-
258
-fin:	ret
259
-
260
-# Part of above routine, this one just prints ascii al
261
-prtchr:	pushw	%ax
262
-	pushw	%cx
263
-	movw	$7,%bx
264
-	movw	$0x01, %cx
265
-	movb	$0x0e, %ah
266
-	int	$0x10
267
-	popw	%cx
268
-	popw	%ax
269
-	ret
270
-
271
-no_sig_mess: .string	"No setup signature found ..."
272
-
273
-good_sig1:
274
-	jmp	good_sig
275
-
276
-# We now have to find the rest of the setup code/data
277
-bad_sig:
278
-	movw	%cs, %ax			# SETUPSEG
279
-	subw	$DELTA_INITSEG, %ax		# INITSEG
280
-	movw	%ax, %ds
281
-	xorb	%bh, %bh
282
-	movb	(497), %bl			# get setup sect from bootsect
283
-	subw	$4, %bx				# LILO loads 4 sectors of setup
284
-	shlw	$8, %bx				# convert to words (1sect=2^8 words)
285
-	movw	%bx, %cx
286
-	shrw	$3, %bx				# convert to segment
287
-	addw	$SYSSEG, %bx
288
-	movw	%bx, %cs:(start_sys_seg - setup_code)
289
-# Move rest of setup code/data to here
290
-	movw	$2048, %di			# four sectors loaded by LILO
291
-	subw	%si, %si
292
-	pushw	%cs
293
-	popw	%es
294
-	movw	$SYSSEG, %ax
295
-	movw	%ax, %ds
296
-	rep
297
-	movsw
298
-	movw	%cs, %ax			# aka SETUPSEG
299
-	movw	%ax, %ds
300
-	cmpw	$SIG1, (setup_sig1 - setup_code)
301
-	jne	no_sig
302
-
303
-	cmpw	$SIG2, (setup_sig2 - setup_code)
304
-	jne	no_sig
305
-
306
-	jmp	good_sig
307
-
308
-no_sig:
309
-	lea	(no_sig_mess - setup_code), %si
310
-	call	prtstr
311
-
312
-no_sig_loop:
313
-	hlt
314
-	jmp	no_sig_loop
315
-
316
-good_sig:
317
-	cmpw	$0, %cs:(realmode_swtch - setup_code)
318
-	jz	rmodeswtch_normal
319
-
320
-	lcall	*%cs:(realmode_swtch - setup_code)
321
-	jmp	rmodeswtch_end
322
-
323
-rmodeswtch_normal:
324
-	pushw	%cs
325
-	call	default_switch
326
-
327
-rmodeswtch_end:
328
-# we get the code32 start address and modify the below 'jmpi'
329
-# (loader may have changed it)
330
-	movl	%cs:(code32_start - setup_code), %eax
331
-	movl	%eax, %cs:(code32 - setup_code)
332
-
333
-# then we load the segment descriptors
334
-	movw	%cs, %ax			# aka SETUPSEG
335
-	movw	%ax, %ds
336
-
337
-#
338
-# Enable A20.  This is at the very best an annoying procedure.
339
-# A20 code ported from SYSLINUX 1.52-1.63 by H. Peter Anvin.
340
-#
341
-
342
-A20_TEST_LOOPS		=  32		# Iterations per wait
343
-A20_ENABLE_LOOPS	= 255		# Total loops to try		
344
-
345
-a20_try_loop:
346
-
347
-	# First, see if we are on a system with no A20 gate.
348
-a20_none:
349
-	call	a20_test
350
-	jnz	a20_done
351
-
352
-	# Next, try the BIOS (INT 0x15, AX=0x2401)
353
-a20_bios:
354
-	movw	$0x2401, %ax
355
-	pushfl					# Be paranoid about flags
356
-	int	$0x15
357
-	popfl
358
-
359
-	call	a20_test
360
-	jnz	a20_done
361
-
362
-	# Try enabling A20 through the keyboard controller
363
-a20_kbc:
364
-	call	empty_8042
365
-
366
-	call	a20_test			# Just in case the BIOS worked
367
-	jnz	a20_done			# but had a delayed reaction.
368
-
369
-	movb	$0xD1, %al			# command write
370
-	outb	%al, $0x64
371
-	call	empty_8042
372
-
373
-	movb	$0xDF, %al			# A20 on
374
-	outb	%al, $0x60
375
-	call	empty_8042
376
-
377
-	# Wait until a20 really *is* enabled; it can take a fair amount of
378
-	# time on certain systems; Toshiba Tecras are known to have this
379
-	# problem.
380
-a20_kbc_wait:
381
-	xorw	%cx, %cx
382
-a20_kbc_wait_loop:
383
-	call	a20_test
384
-	jnz	a20_done
385
-	loop	a20_kbc_wait_loop
386
-
387
-	# Final attempt: use "configuration port A"
388
-a20_fast:
389
-	inb	$0x92, %al			# Configuration Port A
390
-	orb	$0x02, %al			# "fast A20" version
391
-	andb	$0xFE, %al			# don't accidentally reset
392
-	outb	%al, $0x92
393
-
394
-	# Wait for configuration port A to take effect
395
-a20_fast_wait:
396
-	xorw	%cx, %cx
397
-a20_fast_wait_loop:
398
-	call	a20_test
399
-	jnz	a20_done
400
-	loop	a20_fast_wait_loop
401
-
402
-	# A20 is still not responding.  Try frobbing it again.
403
-	# 
404
-	decb	(a20_tries - setup_code)
405
-	jnz	a20_try_loop
406
-	
407
-	movw	$(a20_err_msg - setup_code), %si
408
-	call	prtstr
409
-
410
-a20_die:
411
-	hlt
412
-	jmp	a20_die
413
-
414
-a20_tries:
415
-	.byte	A20_ENABLE_LOOPS
416
-
417
-a20_err_msg:
418
-	.ascii	"linux: fatal error: A20 gate not responding!"
419
-	.byte	13, 10, 0
420
-
421
-	# If we get here, all is good
422
-a20_done:
423
-	# Leave the idt alone
424
-	
425
-	# set up gdt 
426
-	xorl	%eax, %eax				# Compute gdt_base
427
-	movw	%ds, %ax				# (Convert %ds:gdt to a linear ptr)
428
-	shll	$4, %eax
429
-	addl	$(bImage_gdt - setup_code), %eax
430
-	movl	%eax, (bImage_gdt_48+2 - setup_code)
431
-	DATA32 lgdt %ds:(bImage_gdt_48 - setup_code)	# load gdt with whatever is
432
-							# appropriate
433
-
434
-	# Switch to protected mode
435
-	movl	%cr0, %eax
436
-	orb	$CR0_PE, %al
437
-	movl	%eax, %cr0
438
-
439
-	DATA32 ljmp *%ds:(code32 - setup_code)
440
-code32:
441
-	.long	0x100000
442
-	.word	__BOOT_CS, 0
443
-	
444
-# Here's a bunch of information about your current kernel..
445
-kernel_version:	.ascii	"Etherboot "
446
-		.ascii	VERSION
447
-		.byte	0
448
-
449
-# This is the default real mode switch routine.
450
-# to be called just before protected mode transition
451
-default_switch:
452
-	cli					# no interrupts allowed !
453
-	movb	$0x80, %al			# disable NMI for bootup
454
-						# sequence
455
-	outb	%al, $0x70
456
-	lret
457
-
458
-# This routine tests whether or not A20 is enabled.  If so, it
459
-# exits with zf = 0.
460
-#
461
-# The memory address used, 0x200, is the int $0x80 vector, which
462
-# should be safe.
463
-
464
-A20_TEST_ADDR = 4*0x80
465
-
466
-a20_test:
467
-	pushw	%cx
468
-	pushw	%ax
469
-	xorw	%cx, %cx
470
-	movw	%cx, %fs			# Low memory
471
-	decw	%cx
472
-	movw	%cx, %gs			# High memory area
473
-	movw	$A20_TEST_LOOPS, %cx
474
-	movw	%fs:(A20_TEST_ADDR), %ax
475
-	pushw	%ax
476
-a20_test_wait:
477
-	incw	%ax
478
-	movw	%ax, %fs:(A20_TEST_ADDR)
479
-	call	delay				# Serialize and make delay constant
480
-	cmpw	%gs:(A20_TEST_ADDR+0x10), %ax
481
-	loope	a20_test_wait
482
-
483
-	popw	%fs:(A20_TEST_ADDR)
484
-	popw	%ax
485
-	popw	%cx
486
-	ret	
487
-
488
-
489
-# This routine checks that the keyboard command queue is empty
490
-# (after emptying the output buffers)
491
-#
492
-# Some machines have delusions that the keyboard buffer is always full
493
-# with no keyboard attached...
494
-#
495
-# If there is no keyboard controller, we will usually get 0xff
496
-# to all the reads.  With each IO taking a microsecond and
497
-# a timeout of 100,000 iterations, this can take about half a
498
-# second ("delay" == outb to port 0x80). That should be ok,
499
-# and should also be plenty of time for a real keyboard controller
500
-# to empty.
501
-#
502
-
503
-empty_8042:
504
-	pushl	%ecx
505
-	movl	$100000, %ecx
506
-
507
-empty_8042_loop:
508
-	decl	%ecx
509
-	jz	empty_8042_end_loop
510
-
511
-	call	delay
512
-
513
-	inb	$0x64, %al			# 8042 status port
514
-	testb	$1, %al				# output buffer?
515
-	jz	no_output
516
-
517
-	call	delay
518
-	inb	$0x60, %al			# read it
519
-	jmp	empty_8042_loop
520
-
521
-no_output:
522
-	testb	$2, %al				# is input buffer full?
523
-	jnz	empty_8042_loop			# yes - loop
524
-empty_8042_end_loop:
525
-	popl	%ecx
526
-
527
-		
528
-# Delay is needed after doing I/O
529
-delay:
530
-	outb	%al,$0x80
531
-	ret
532
-
533
-# Descriptor tables
534
-#
535
-# NOTE: The intel manual says gdt should be sixteen bytes aligned for
536
-# efficiency reasons.  However, there are machines which are known not
537
-# to boot with misaligned GDTs, so alter this at your peril!  If you alter
538
-# GDT_ENTRY_BOOT_CS (in asm/segment.h) remember to leave at least two
539
-# empty GDT entries (one for NULL and one reserved).
540
-#
541
-# NOTE:	On some CPUs, the GDT must be 8 byte aligned.  This is
542
-# true for the Voyager Quad CPU card which will not boot without
543
-# This directive.  16 byte aligment is recommended by intel.
544
-#
545
-	.balign 16
546
-bImage_gdt:
547
-	.fill GDT_ENTRY_BOOT_CS,8,0
548
-
549
-	.word	0xFFFF				# 4Gb - (0x100000*0x1000 = 4Gb)
550
-	.word	0				# base address = 0
551
-	.word	0x9A00				# code read/exec
552
-	.word	0x00CF				# granularity = 4096, 386
553
-						#  (+5th nibble of limit)
554
-
555
-	.word	0xFFFF				# 4Gb - (0x100000*0x1000 = 4Gb)
556
-	.word	0				# base address = 0
557
-	.word	0x9200				# data read/write
558
-	.word	0x00CF				# granularity = 4096, 386
559
-						#  (+5th nibble of limit)
560
-bImage_gdt_end:
561
-	.balign	4
562
-	
563
-	.word	0				# alignment byte
564
-bImage_idt_48:
565
-	.word	0				# idt limit = 0
566
-	.long	0				# idt base = 0L
567
-
568
-	.word	0				# alignment byte
569
-bImage_gdt_48:
570
-	.word	bImage_gdt_end - bImage_gdt - 1	# gdt limit
571
-	.long	bImage_gdt_48 - setup_code	# gdt base (filled in later)
572
-
573
-	.section ".text16", "ax", @progbits
574
-prefix_exit:
575
-	int	$0x19		/* should try to boot machine */
576
-prefix_exit_end:
577
-	.previous
578
-	
579
-	
580
-	.org (PREFIXSIZE - 4)
581
-# Setup signature -- must be last
582
-setup_sig1:	.word	SIG1
583
-setup_sig2:	.word	SIG2
584
-	/* Etherboot expects to be contiguous in memory once loaded.
585
-	 * The linux bImage protocol does not do this, but since we
586
-	 * don't need any information that's left in the prefix, it
587
-	 * doesn't matter: we just have to ensure that we make it to _start
588
-	 *
589
-	 * protected_start will live at 0x100000 and it will be the
590
-	 * the first code called as we enter protected mode.
591
-	 */
592
-	.code32
593
-protected_start:
594
-	/* Load segment registers */
595
-	movw	$__BOOT_DS, %ax
596
-	movw	%ax, %ss
597
-	movw	%ax, %ds
598
-	movw	%ax, %es
599
-	movw	%ax, %fs
600
-	movw	%ax, %gs
601
-
602
-	/* Use the internal etherboot stack */
603
-	movl	$(_prefix_stack_end - protected_start + 0x100000), %esp
604
-
605
-	pushl	$0		/* No parameters to preserve for exit path */
606
-	pushl	$0		/* Use prefix exit path mechanism */
607
-	
608
-	jmp	_start
609
-/*
610
-	That's about it.
611
-*/

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