xref: /titanic_50/usr/src/cmd/sgs/rtld/sparc/boot_elf.s (revision 3eae19d9cf3390cf5b75e10c9c1945fd36ad856a)
1/*
2 * CDDL HEADER START
3 *
4 * The contents of this file are subject to the terms of the
5 * Common Development and Distribution License (the "License").
6 * You may not use this file except in compliance with the License.
7 *
8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 * or http://www.opensolaris.org/os/licensing.
10 * See the License for the specific language governing permissions
11 * and limitations under the License.
12 *
13 * When distributing Covered Code, include this CDDL HEADER in each
14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 * If applicable, add the following below this CDDL HEADER, with the
16 * fields enclosed by brackets "[]" replaced with your own identifying
17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 *
19 * CDDL HEADER END
20 */
21
22/*
23 *	Copyright (c) 1988 AT&T
24 *	  All Rights Reserved
25 *
26 * Copyright 2007 Sun Microsystems, Inc.  All rights reserved.
27 * Use is subject to license terms.
28 */
29#pragma ident	"%Z%%M%	%I%	%E% SMI"
30
31#include	<link.h>
32#include	"machdep.h"
33#include	"_audit.h"
34
35#if	defined(lint)
36#include	<sys/types.h>
37#include	"_rtld.h"
38#else
39#include	<sys/stack.h>
40#include	<sys/asm_linkage.h>
41
42	.file	"boot_elf.s"
43	.seg	".text"
44#endif
45
46/*
47 * We got here because the initial call to a function resolved to a procedure
48 * linkage table entry.  That entry did a branch to the first PLT entry, which
49 * in turn did a call to elf_rtbndr (refer elf_plt_init()).
50 *
51 * the code sequence that got us here was:
52 *
53 * PLT entry for foo():
54 *	sethi	(.-PLT0), %g1			! not changed by rtld
55 *	ba,a	.PLT0				! patched atomically 2nd
56 *	nop					! patched first
57 *
58 * Therefore on entry, %i7 has the address of the call, which will be added
59 * to the offset to the plt entry in %g1 to calculate the plt entry address
60 * we must also subtract 4 because the address of PLT0 points to the
61 * save instruction before the call.
62 *
63 * the plt entry is rewritten:
64 *
65 * PLT entry for foo():
66 *	sethi	(.-PLT0), %g1
67 *	sethi	%hi(entry_pt), %g1
68 *	jmpl	%g1 + %lo(entry_pt), %g0
69 */
70
71#if	defined(lint)
72
73extern unsigned long	elf_bndr(Rt_map *, unsigned long, caddr_t);
74
75static void
76elf_rtbndr(Rt_map *lmp, unsigned long pltoff, caddr_t from)
77{
78	(void) elf_bndr(lmp, pltoff, from);
79}
80
81
82#else
83	.weak	_elf_rtbndr		! keep dbx happy as it likes to
84	_elf_rtbndr = elf_rtbndr	! rummage around for our symbols
85
86	.global	elf_rtbndr
87	.type   elf_rtbndr, #function
88	.align	4
89
90elf_rtbndr:
91	mov	%i7, %o0		! Save callers address(profiling)
92	save	%sp, -SA(MINFRAME), %sp	! Make a frame
93	srl	%g1, 10, %o1		! shift offset set by sethi
94					! %o1 has offset from jump slot
95					! to PLT0 which will be used to
96					! calculate plt relocation entry
97					! by elf_bndr
98	ld	[%i7 + 8], %o0		! %o0 has ptr to lm
99	call	elf_bndr		! returns function address in %o0
100	mov	%i0, %o2		! Callers address is arg 3
101	mov	%o0, %g1		! save address of routine binded
102	restore				! how many restores needed ? 2
103	jmp	%g1			! jump to it
104	restore
105	.size 	elf_rtbndr, . - elf_rtbndr
106
107#endif
108
109
110#if defined(lint)
111void
112iflush_range(caddr_t addr, size_t len)
113{
114	/* LINTED */
115	uintptr_t base;
116
117	base = (uintptr_t)addr & ~7;	/* round down to 8 byte alignment */
118	len = (len + 7) & ~7;		/* round up to multiple of 8 bytes */
119	for (len -= 8; (long)len >= 0; len -= 8)
120		/* iflush(base + len) */;
121}
122#else
123	ENTRY(iflush_range)
124	add	%o1, 7, %o1
125	andn	%o0, 7, %o0
126	andn	%o1, 7, %o1
1271:	subcc	%o1, 8, %o1
128	bge,a	1b
129	iflush	%o0 + %o1
130	retl
131	nop
132	SET_SIZE(iflush_range)
133#endif
134
135/*
136 * Initialize the first plt entry so that function calls go to elf_rtbndr
137 *
138 * The first plt entry (PLT0) is:
139 *
140 *	save	%sp, -64, %sp
141 *	call	elf_rtbndr
142 *	nop
143 *	address of lm
144 */
145
146#if	defined(lint)
147
148void
149elf_plt_init(void *plt, caddr_t lmp)
150{
151	*((uint_t *)plt + 0) = (unsigned long) M_SAVESP64;
152	*((uint_t *)plt + 4) = M_CALL | (((unsigned long)elf_rtbndr -
153			((unsigned long)plt)) >> 2);
154	*((uint_t *)plt + 8) = M_NOP;
155	*((uint_t *)plt + 12) = (unsigned long) lmp;
156}
157
158#else
159	.global	elf_plt_init
160	.type	elf_plt_init, #function
161	.align	4
162
163elf_plt_init:
164	save	%sp, -SA(MINFRAME), %sp	! Make a frame
1651:
166	call	2f
167	sethi	%hi((_GLOBAL_OFFSET_TABLE_ - (1b - .))), %l7
1682:
169	sethi	%hi(M_SAVESP64), %o0	! Get save instruction
170	or	%o0, %lo(M_SAVESP64), %o0
171	or	%l7, %lo((_GLOBAL_OFFSET_TABLE_ - (1b - .))), %l7
172	st	%o0, [%i0]		! Store in plt[0]
173	iflush	%i0
174	add	%l7, %o7, %l7
175	ld	[%l7 + elf_rtbndr], %l7
176	inc	4, %i0			! Bump plt to point to plt[1]
177	sub	%l7, %i0, %o0		! Determine -pc so as to produce
178					! offset from plt[1]
179	srl	%o0, 2, %o0		! Express offset as number of words
180	sethi	%hi(M_CALL), %o4	! Get sethi instruction
181	or	%o4, %o0, %o4		! Add elf_rtbndr address
182	st	%o4, [%i0]		! Store instruction in plt
183	iflush	%i0
184	sethi	%hi(M_NOP), %o0		! Generate nop instruction
185	st	%o0, [%i0 + 4]		! Store instruction in plt[2]
186	iflush	%i0 + 4
187	st	%i1, [%i0 + 8]		! Store instruction in plt[3]
188	iflush	%i0 + 8
189	ret
190	restore
191	.size	elf_plt_init, . - elf_plt_init
192#endif
193
194#if	defined(lint)
195
196ulong_t
197elf_plt_trace()
198{
199	return (0);
200}
201#else
202	.global	elf_plt_trace
203	.type   elf_plt_trace, #function
204	.align	4
205
206/*
207 * The dyn_plt that called us has already created a stack-frame for
208 * us and placed the following entries in it:
209 *
210 *	[%fp - 0x4]	* dyndata
211 *	[%fp - 0x8]	* prev stack size
212 *
213 * dyndata currently contains:
214 *
215 *	dyndata:
216 *	0x0	uintptr_t	*reflmp
217 *	0x4	uintptr_t	*deflmp
218 *	0x8	ulong_t		symndx
219 *	0xc	ulong_t		sb_flags
220 *	0x10	Sym		symdef.st_name
221 *	0x14			symdef.st_value
222 *	0x18			symdef.st_size
223 *	0x1c			symdef.st_info
224 *	0x1d			symdef.st_other
225 *	0x1e			symdef.st_shndx
226 */
227#define	REFLMP_OFF		0x0
228#define	DEFLMP_OFF		0x4
229#define	SYMNDX_OFF		0x8
230#define	SBFLAGS_OFF		0xc
231#define	SYMDEF_OFF		0x10
232#define	SYMDEF_VALUE_OFF	0x14
233
234elf_plt_trace:
2351:	call	2f
236	sethi	%hi(_GLOBAL_OFFSET_TABLE_+(.-1b)), %l7
2372:	or	%l7, %lo(_GLOBAL_OFFSET_TABLE_+(.-1b)), %l7
238	add	%l7, %o7, %l7
239
240	ld	[%l7+audit_flags], %l3
241	ld	[%l3], %l3		! %l3 = audit_flags
242	andcc	%l3, AF_PLTENTER, %g0
243	beq	.end_pltenter
244	ld	[%fp + -0x4], %l1	! l1 = * dyndata
245	ld	[%l1 + SBFLAGS_OFF], %l2 ! l2 = sb_flags
246	andcc	%l2, LA_SYMB_NOPLTENTER, %g0
247	beq	.start_pltenter
248	ld	[%l1 + SYMDEF_VALUE_OFF], %l0	! l0 =
249						!  sym.st_value(calling address)
250	ba	.end_pltenter
251	nop
252
253	/*
254	 * save all registers into La_sparcv8_regs
255	 */
256.start_pltenter:
257	sub	%sp, 0x20, %sp		! create space for La_sparcv8_regs
258					! storage on the stack.
259
260	sub	%fp, 0x28, %o4
261
262	st	%i0, [%o4]
263	st	%i1, [%o4 + 0x4]
264	st	%i2, [%o4 + 0x8]
265	st	%i3, [%o4 + 0xc]	! because a regwindow shift has
266	st	%i4, [%o4 + 0x10]	! already occured our current %i*
267	st	%i5, [%o4 + 0x14]	! register's are the equivalent of
268	st	%i6, [%o4 + 0x18]	! the %o* registers that the final
269	st	%i7, [%o4 + 0x1c]	! procedure shall see.
270
271	ld	[%fp + -0x4], %l1	! %l1 == * dyndata
272	ld	[%l1 + REFLMP_OFF], %o0	! %o0 = reflmp
273	ld	[%l1 + DEFLMP_OFF], %o1	! %o1 = deflmp
274	add	%l1, SYMDEF_OFF, %o2	! %o2 = symp
275	ld	[%l1 + SYMNDX_OFF], %o3	! %o3 = symndx
276	call	audit_pltenter
277	add	%l1, SBFLAGS_OFF, %o5	! %o3 = * sb_flags
278
279	mov	%o0, %l0		! %l0 == calling address
280
281	add	%sp, 0x20, %sp		! cleanup La_sparcv8_regs off
282					! of the stack.
283
284.end_pltenter:
285	/*
286	 * If *no* la_pltexit() routines exist we do not need to keep the
287	 * stack frame before we call the actual routine.  Instead we jump to
288	 * it and remove our self from the stack at the same time.
289	 */
290	ld	[%l7+audit_flags], %l3
291	ld	[%l3], %l3		! %l3 = audit_flags
292	andcc	%l3, AF_PLTEXIT, %g0
293	beq	.bypass_pltexit
294	ld	[%fp + -0x4], %l1	! %l1 = * dyndata
295	ld	[%l1 + SBFLAGS_OFF], %l2 ! %l2 = sb_flags
296	andcc	%l2, LA_SYMB_NOPLTEXIT, %g0
297	bne	.bypass_pltexit
298	nop
299
300	ba	.start_pltexit
301	nop
302.bypass_pltexit:
303	jmpl	%l0, %g0
304	restore
305
306.start_pltexit:
307	/*
308	 * In order to call la_pltexit() we must duplicate the
309	 * arguments from the 'callers' stack on our stack frame.
310	 *
311	 * First we check the size of the callers stack and grow
312	 * our stack to hold any of the arguments.  That need
313	 * duplicating (these are arguments 6->N), because the
314	 * first 6 (0->5) are passed via register windows on sparc.
315	 */
316
317	/*
318	 * The first calculation is to determine how large the
319	 * argument passing area might be.  Since there is no
320	 * way to distinquish between 'argument passing' and
321	 * 'local storage' from the previous stack this amount must
322	 * cover both.
323	 */
324	ld	[%fp + -0x8], %l1	! %l1 = callers stack size
325	sub	%l1, 0x58, %l1		! %l1 = argument space on caller's
326					!	stack
327	/*
328	 * Next we compare the prev. stack size against the audit_argcnt.
329	 * We copy at most 'audit_argcnt' arguments.
330	 *
331	 * NOTE: on sparc we always copy at least six args since these
332	 *	 are in reg-windows and not on the stack.
333	 *
334	 * NOTE: Also note that we multiply (shift really) the arg count
335	 *	 by 4 which is the 'word size' to calculate the amount
336	 *	 of stack space needed.
337	 */
338	ld	[%l7 + audit_argcnt], %l2
339	ld	[%l2], %l2		! %l2 = audit_arg_count
340	cmp	%l2, 6
341	ble	.grow_stack
342	sub	%l2, 6, %l2
343	sll	%l2, 2, %l2
344	cmp	%l1, %l2
345	ble	.grow_stack
346	nop
347	mov	%l2, %l1
348.grow_stack:
349	/*
350	 * When duplicating the stack we skip the first '0x5c' bytes.
351	 * This is the space on the stack reserved for preserving
352	 * the register windows and such and do not need to be duplicated
353	 * on this new stack frame.  We start duplicating at the
354	 * portion of the stack reserved for argument's above 6.
355	 */
356	sub	%sp, %l1, %sp		! grow our stack by amount required.
357	sra	%l1, 0x2, %l1		! %l1 = %l1 / 4 (words to copy)
358	mov	0x5c, %l2		! %l2 = index into stack & frame
359
3601:
361	cmp	%l1, 0
362	ble	2f
363	nop
364	ld	[%fp + %l2], %l3	! duplicate args from previous
365	st	%l3, [%sp + %l2]	! stack onto current stack
366	add	%l2, 0x4, %l2
367	ba	1b
368	sub	%l1, 0x1, %l1
3692:
370	mov	%i0, %o0		! copy ins to outs
371	mov	%i1, %o1
372	mov	%i2, %o2
373	mov	%i3, %o3
374	mov	%i4, %o4
375	call	%l0			! call routine
376	mov	%i5, %o5
377	mov	%o1, %l2		! l2 = second 1/2 of return value
378					! for those those 64 bit operations
379					! link div64 - yuck...
380
381					! %o0 = retval
382	ld	[%fp + -0x4], %l1
383	ld	[%l1 + REFLMP_OFF], %o1	! %o1 = reflmp
384	ld	[%l1 + DEFLMP_OFF], %o2	! %o2 = deflmp
385	add	%l1, SYMDEF_OFF, %o3	! %o3 = symp
386	call	audit_pltexit
387	ld	[%l1 + SYMNDX_OFF], %o4	! %o4 = symndx
388
389	mov	%o0, %i0		! pass on return code
390	mov	%l2, %i1
391	ret
392	restore
393	.size	elf_plt_trace, . - elf_plt_trace
394
395#endif
396
397/*
398 * After the first call to a plt, elf_bndr() will have determined the true
399 * address of the function being bound.  The plt is now rewritten so that
400 * any subsequent calls go directly to the bound function.  If the library
401 * to which the function belongs is being profiled refer to _plt_cg_write.
402 *
403 * the new plt entry is:
404 *
405 *	sethi	(.-PLT0), %g1			! constant
406 *	sethi	%hi(function address), %g1	! patched second
407 *	jmpl	%g1 + %lo(function address, %g0	! patched first
408 */
409
410#if	defined(lint)
411
412void
413plt_full_range(uintptr_t pc, uintptr_t symval)
414{
415	uint_t *	plttab = (uint_t *)pc;
416	plttab[2] = (M_JMPL | ((unsigned long)symval & S_MASK(10)));
417	plttab[1] = (M_SETHIG1 | ((unsigned long)symval >> (32 - 22)));
418}
419
420#else
421	ENTRY(plt_full_range)
422
423	sethi	%hi(M_JMPL), %o3	! Get jmpl instruction
424	and	%o1, 0x3ff, %o2		! Lower part of function address
425	or	%o3, %o2, %o3		!	is or'ed into instruction
426	st	%o3, [%o0 + 8]		! Store instruction in plt[2]
427	iflush	%o0 + 8
428	stbar
429
430	srl	%o1, 10, %o1		! Get high part of function address
431	sethi	%hi(M_SETHIG1), %o3	! Get sethi instruction
432	or	%o3, %o1, %o3		! Add sethi and function address
433	st	%o3, [%o0 + 4]		! Store instruction in plt[1]
434	retl
435	iflush	%o0 + 4
436
437	SET_SIZE(plt_full_range)
438
439#endif	/* defined(lint) */
440
441