| blob | 843feb94a950168c60319e127f4df4568e1beb3c |
1 /*
2 * User-space Probes (UProbes) for x86
3 *
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
8 *
9 * This program is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, write to the Free Software
16 * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
17 *
18 * Copyright (C) IBM Corporation, 2008-2011
19 * Authors:
20 * Srikar Dronamraju
21 * Jim Keniston
22 */
23 #include <linux/kernel.h>
24 #include <linux/sched.h>
25 #include <linux/ptrace.h>
26 #include <linux/uprobes.h>
27 #include <linux/uaccess.h>
29 #include <linux/kdebug.h>
30 #include <asm/processor.h>
31 #include <asm/insn.h>
32 #include <asm/mmu_context.h>
34 /* Post-execution fixups. */
36 /* Adjust IP back to vicinity of actual insn */
37 #define UPROBE_FIX_IP 0x01
39 /* Adjust the return address of a call insn */
40 #define UPROBE_FIX_CALL 0x02
42 /* Instruction will modify TF, don't change it */
43 #define UPROBE_FIX_SETF 0x04
45 #define UPROBE_FIX_RIP_SI 0x08
46 #define UPROBE_FIX_RIP_DI 0x10
47 #define UPROBE_FIX_RIP_BX 0x20
48 #define UPROBE_FIX_RIP_MASK \
49 (UPROBE_FIX_RIP_SI | UPROBE_FIX_RIP_DI | UPROBE_FIX_RIP_BX)
51 #define UPROBE_TRAP_NR UINT_MAX
53 /* Adaptations for mhiramat x86 decoder v14. */
54 #define OPCODE1(insn) ((insn)->opcode.bytes[0])
55 #define OPCODE2(insn) ((insn)->opcode.bytes[1])
56 #define OPCODE3(insn) ((insn)->opcode.bytes[2])
57 #define MODRM_REG(insn) X86_MODRM_REG((insn)->modrm.value)
59 #define W(row, b0, b1, b2, b3, b4, b5, b6, b7, b8, b9, ba, bb, bc, bd, be, bf)\
60 (((b0##UL << 0x0)|(b1##UL << 0x1)|(b2##UL << 0x2)|(b3##UL << 0x3) | \
61 (b4##UL << 0x4)|(b5##UL << 0x5)|(b6##UL << 0x6)|(b7##UL << 0x7) | \
62 (b8##UL << 0x8)|(b9##UL << 0x9)|(ba##UL << 0xa)|(bb##UL << 0xb) | \
63 (bc##UL << 0xc)|(bd##UL << 0xd)|(be##UL << 0xe)|(bf##UL << 0xf)) \
64 << (row % 32))
66 /*
67 * Good-instruction tables for 32-bit apps. This is non-const and volatile
68 * to keep gcc from statically optimizing it out, as variable_test_bit makes
69 * some versions of gcc to think only *(unsigned long*) is used.
70 *
71 * Opcodes we'll probably never support:
72 * 6c-6f - ins,outs. SEGVs if used in userspace
73 * e4-e7 - in,out imm. SEGVs if used in userspace
74 * ec-ef - in,out acc. SEGVs if used in userspace
75 * cc - int3. SIGTRAP if used in userspace
76 * ce - into. Not used in userspace - no kernel support to make it useful. SEGVs
77 * (why we support bound (62) then? it's similar, and similarly unused...)
78 * f1 - int1. SIGTRAP if used in userspace
79 * f4 - hlt. SEGVs if used in userspace
80 * fa - cli. SEGVs if used in userspace
81 * fb - sti. SEGVs if used in userspace
82 *
83 * Opcodes which need some work to be supported:
84 * 07,17,1f - pop es/ss/ds
85 * Normally not used in userspace, but would execute if used.
86 * Can cause GP or stack exception if tries to load wrong segment descriptor.
87 * We hesitate to run them under single step since kernel's handling
88 * of userspace single-stepping (TF flag) is fragile.
89 * We can easily refuse to support push es/cs/ss/ds (06/0e/16/1e)
90 * on the same grounds that they are never used.
91 * cd - int N.
92 * Used by userspace for "int 80" syscall entry. (Other "int N"
93 * cause GP -> SEGV since their IDT gates don't allow calls from CPL 3).
94 * Not supported since kernel's handling of userspace single-stepping
95 * (TF flag) is fragile.
96 * cf - iret. Normally not used in userspace. Doesn't SEGV unless arguments are bad
97 */
98 #if defined(CONFIG_X86_32) || defined(CONFIG_IA32_EMULATION)
100 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
101 /* ---------------------------------------------- */
118 /* ---------------------------------------------- */
119 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
120 };
121 #else
122 #define good_insns_32 NULL
123 #endif
125 /* Good-instruction tables for 64-bit apps.
126 *
127 * Genuinely invalid opcodes:
128 * 06,07 - formerly push/pop es
129 * 0e - formerly push cs
130 * 16,17 - formerly push/pop ss
131 * 1e,1f - formerly push/pop ds
132 * 27,2f,37,3f - formerly daa/das/aaa/aas
133 * 60,61 - formerly pusha/popa
134 * 62 - formerly bound. EVEX prefix for AVX512 (not yet supported)
135 * 82 - formerly redundant encoding of Group1
136 * 9a - formerly call seg:ofs
137 * ce - formerly into
138 * d4,d5 - formerly aam/aad
139 * d6 - formerly undocumented salc
140 * ea - formerly jmp seg:ofs
141 *
142 * Opcodes we'll probably never support:
143 * 6c-6f - ins,outs. SEGVs if used in userspace
144 * e4-e7 - in,out imm. SEGVs if used in userspace
145 * ec-ef - in,out acc. SEGVs if used in userspace
146 * cc - int3. SIGTRAP if used in userspace
147 * f1 - int1. SIGTRAP if used in userspace
148 * f4 - hlt. SEGVs if used in userspace
149 * fa - cli. SEGVs if used in userspace
150 * fb - sti. SEGVs if used in userspace
151 *
152 * Opcodes which need some work to be supported:
153 * cd - int N.
154 * Used by userspace for "int 80" syscall entry. (Other "int N"
155 * cause GP -> SEGV since their IDT gates don't allow calls from CPL 3).
156 * Not supported since kernel's handling of userspace single-stepping
157 * (TF flag) is fragile.
158 * cf - iret. Normally not used in userspace. Doesn't SEGV unless arguments are bad
159 */
160 #if defined(CONFIG_X86_64)
162 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
163 /* ---------------------------------------------- */
180 /* ---------------------------------------------- */
181 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
182 };
183 #else
184 #define good_insns_64 NULL
185 #endif
187 /* Using this for both 64-bit and 32-bit apps.
188 * Opcodes we don't support:
189 * 0f 00 - SLDT/STR/LLDT/LTR/VERR/VERW/-/- group. System insns
190 * 0f 01 - SGDT/SIDT/LGDT/LIDT/SMSW/-/LMSW/INVLPG group.
191 * Also encodes tons of other system insns if mod=11.
192 * Some are in fact non-system: xend, xtest, rdtscp, maybe more
193 * 0f 05 - syscall
194 * 0f 06 - clts (CPL0 insn)
195 * 0f 07 - sysret
196 * 0f 08 - invd (CPL0 insn)
197 * 0f 09 - wbinvd (CPL0 insn)
198 * 0f 0b - ud2
199 * 0f 30 - wrmsr (CPL0 insn) (then why rdmsr is allowed, it's also CPL0 insn?)
200 * 0f 34 - sysenter
201 * 0f 35 - sysexit
202 * 0f 37 - getsec
203 * 0f 78 - vmread (Intel VMX. CPL0 insn)
204 * 0f 79 - vmwrite (Intel VMX. CPL0 insn)
205 * Note: with prefixes, these two opcodes are
206 * extrq/insertq/AVX512 convert vector ops.
207 * 0f ae - group15: [f]xsave,[f]xrstor,[v]{ld,st}mxcsr,clflush[opt],
208 * {rd,wr}{fs,gs}base,{s,l,m}fence.
209 * Why? They are all user-executable.
210 */
212 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
213 /* ---------------------------------------------- */
230 /* ---------------------------------------------- */
231 /* 0 1 2 3 4 5 6 7 8 9 a b c d e f */
232 };
233 #undef W
235 /*
236 * opcodes we may need to refine support for:
237 *
238 * 0f - 2-byte instructions: For many of these instructions, the validity
239 * depends on the prefix and/or the reg field. On such instructions, we
240 * just consider the opcode combination valid if it corresponds to any
241 * valid instruction.
242 *
243 * 8f - Group 1 - only reg = 0 is OK
244 * c6-c7 - Group 11 - only reg = 0 is OK
245 * d9-df - fpu insns with some illegal encodings
246 * f2, f3 - repnz, repz prefixes. These are also the first byte for
247 * certain floating-point instructions, such as addsd.
248 *
249 * fe - Group 4 - only reg = 0 or 1 is OK
250 * ff - Group 5 - only reg = 0-6 is OK
251 *
252 * others -- Do we need to support these?
253 *
254 * 0f - (floating-point?) prefetch instructions
255 * 07, 17, 1f - pop es, pop ss, pop ds
256 * 26, 2e, 36, 3e - es:, cs:, ss:, ds: segment prefixes --
257 * but 64 and 65 (fs: and gs:) seem to be used, so we support them
258 * 67 - addr16 prefix
259 * ce - into
260 * f0 - lock prefix
261 */
263 /*
264 * TODO:
265 * - Where necessary, examine the modrm byte and allow only valid instructions
266 * in the different Groups and fpu instructions.
267 */
270 {
274 insn_attr_t attr;
284 }
285 }
287 }
290 {
294 /* has the side-effect of processing the entire instruction */
302 /* We should not singlestep on the exception masking instructions */
308 else
317 }
320 }
322 #ifdef CONFIG_X86_64
323 /*
324 * If arch_uprobe->insn doesn't use rip-relative addressing, return
325 * immediately. Otherwise, rewrite the instruction so that it accesses
326 * its memory operand indirectly through a scratch register. Set
327 * defparam->fixups accordingly. (The contents of the scratch register
328 * will be saved before we single-step the modified instruction,
329 * and restored afterward).
330 *
331 * We do this because a rip-relative instruction can access only a
332 * relatively small area (+/- 2 GB from the instruction), and the XOL
333 * area typically lies beyond that area. At least for instructions
334 * that store to memory, we can't execute the original instruction
335 * and "fix things up" later, because the misdirected store could be
336 * disastrous.
337 *
338 * Some useful facts about rip-relative instructions:
339 *
340 * - There's always a modrm byte with bit layout "00 reg 101".
341 * - There's never a SIB byte.
342 * - The displacement is always 4 bytes.
343 * - REX.B=1 bit in REX prefix, which normally extends r/m field,
344 * has no effect on rip-relative mode. It doesn't make modrm byte
345 * with r/m=101 refer to register 1101 = R13.
346 */
348 {
350 u8 reg;
351 u8 reg2;
356 /*
357 * insn_rip_relative() would have decoded rex_prefix, vex_prefix, modrm.
358 * Clear REX.b bit (extension of MODRM.rm field):
359 * we want to encode low numbered reg, not r8+.
360 */
363 /* REX byte has 0100wrxb layout, clearing REX.b bit */
365 }
366 /*
367 * Similar treatment for VEX3/EVEX prefix.
368 * TODO: add XOP treatment when insn decoder supports them
369 */
371 /*
372 * vex2: c5 rvvvvLpp (has no b bit)
373 * vex3/xop: c4/8f rxbmmmmm wvvvvLpp
374 * evex: 62 rxbR00mm wvvvv1pp zllBVaaa
375 * Setting VEX3.b (setting because it has inverted meaning).
376 * Setting EVEX.x since (in non-SIB encoding) EVEX.x
377 * is the 4th bit of MODRM.rm, and needs the same treatment.
378 * For VEX3-encoded insns, VEX3.x value has no effect in
379 * non-SIB encoding, the change is superfluous but harmless.
380 */
383 }
385 /*
386 * Convert from rip-relative addressing to register-relative addressing
387 * via a scratch register.
388 *
389 * This is tricky since there are insns with modrm byte
390 * which also use registers not encoded in modrm byte:
391 * [i]div/[i]mul: implicitly use dx:ax
392 * shift ops: implicitly use cx
393 * cmpxchg: implicitly uses ax
394 * cmpxchg8/16b: implicitly uses dx:ax and bx:cx
395 * Encoding: 0f c7/1 modrm
396 * The code below thinks that reg=1 (cx), chooses si as scratch.
397 * mulx: implicitly uses dx: mulx r/m,r1,r2 does r1:r2 = dx * r/m.
398 * First appeared in Haswell (BMI2 insn). It is vex-encoded.
399 * Example where none of bx,cx,dx can be used as scratch reg:
400 * c4 e2 63 f6 0d disp32 mulx disp32(%rip),%ebx,%ecx
401 * [v]pcmpistri: implicitly uses cx, xmm0
402 * [v]pcmpistrm: implicitly uses xmm0
403 * [v]pcmpestri: implicitly uses ax, dx, cx, xmm0
404 * [v]pcmpestrm: implicitly uses ax, dx, xmm0
405 * Evil SSE4.2 string comparison ops from hell.
406 * maskmovq/[v]maskmovdqu: implicitly uses (ds:rdi) as destination.
407 * Encoding: 0f f7 modrm, 66 0f f7 modrm, vex-encoded: c5 f9 f7 modrm.
408 * Store op1, byte-masked by op2 msb's in each byte, to (ds:rdi).
409 * AMD says it has no 3-operand form (vex.vvvv must be 1111)
410 * and that it can have only register operands, not mem
411 * (its modrm byte must have mode=11).
412 * If these restrictions will ever be lifted,
413 * we'll need code to prevent selection of di as scratch reg!
414 *
415 * Summary: I don't know any insns with modrm byte which
416 * use SI register implicitly. DI register is used only
417 * by one insn (maskmovq) and BX register is used
418 * only by one too (cmpxchg8b).
419 * BP is stack-segment based (may be a problem?).
420 * AX, DX, CX are off-limits (many implicit users).
421 * SP is unusable (it's stack pointer - think about "pop mem";
422 * also, rsp+disp32 needs sib encoding -> insn length change).
423 */
429 /*
430 * TODO: add XOP vvvv reading.
431 *
432 * vex.vvvv field is in bits 6-3, bits are inverted.
433 * But in 32-bit mode, high-order bit may be ignored.
434 * Therefore, let's consider only 3 low-order bits.
435 */
437 /*
438 * Register numbering is ax,cx,dx,bx, sp,bp,si,di, r8..r15.
439 *
440 * Choose scratch reg. Order is important: must not select bx
441 * if we can use si (cmpxchg8b case!)
442 */
449 /* TODO (paranoia): force maskmovq to not use di */
453 }
454 /*
455 * Point cursor at the modrm byte. The next 4 bytes are the
456 * displacement. Beyond the displacement, for some instructions,
457 * is the immediate operand.
458 */
460 /*
461 * Change modrm from "00 reg 101" to "10 reg reg2". Example:
462 * 89 05 disp32 mov %eax,disp32(%rip) becomes
463 * 89 86 disp32 mov %eax,disp32(%rsi)
464 */
466 }
470 {
476 }
478 /*
479 * If we're emulating a rip-relative instruction, save the contents
480 * of the scratch register and store the target address in that register.
481 */
483 {
490 }
491 }
494 {
500 }
501 }
503 /*
504 * No RIP-relative addressing on 32-bit
505 */
507 {
508 }
510 {
511 }
513 {
514 }
522 };
525 {
527 }
530 {
533 }
536 {
544 }
546 /*
547 * We have to fix things up as follows:
548 *
549 * Typically, the new ip is relative to the copied instruction. We need
550 * to make it relative to the original instruction (FIX_IP). Exceptions
551 * are return instructions and absolute or indirect jump or call instructions.
552 *
553 * If the single-stepped instruction was a call, the return address that
554 * is atop the stack is the address following the copied instruction. We
555 * need to make it the address following the original instruction (FIX_CALL).
556 *
557 * If the original instruction was a rip-relative instruction such as
558 * "movl %edx,0xnnnn(%rip)", we have instead executed an equivalent
559 * instruction using a scratch register -- e.g., "movl %edx,0xnnnn(%rsi)".
560 * We need to restore the contents of the scratch register
561 * (FIX_RIP_reg).
562 */
564 {
575 }
576 /* popf; tell the caller to not touch TF */
581 }
584 {
586 }
592 };
595 {
597 }
599 #define CASE_COND \
600 COND(70, 71, XF(OF)) \
601 COND(72, 73, XF(CF)) \
602 COND(74, 75, XF(ZF)) \
603 COND(78, 79, XF(SF)) \
604 COND(7a, 7b, XF(PF)) \
605 COND(76, 77, XF(CF) || XF(ZF)) \
606 COND(7c, 7d, XF(SF) != XF(OF)) \
607 COND(7e, 7f, XF(ZF) || XF(SF) != XF(OF))
609 #define COND(op_y, op_n, expr) \
610 case 0x ## op_y: DO((expr) != 0) \
611 case 0x ## op_n: DO((expr) == 0)
613 #define XF(xf) (!!(flags & X86_EFLAGS_ ## xf))
616 {
618 #define DO(expr) \
619 return true;
620 CASE_COND
621 #undef DO
625 }
626 }
629 {
633 #define DO(expr) \
634 return expr;
635 CASE_COND
636 #undef DO
640 }
641 }
643 #undef XF
644 #undef COND
645 #undef CASE_COND
648 {
653 /*
654 * If it fails we execute this (mangled, see the comment in
655 * branch_clear_offset) insn out-of-line. In the likely case
656 * this should trigger the trap, and the probed application
657 * should die or restart the same insn after it handles the
658 * signal, arch_uprobe_post_xol() won't be even called.
659 *
660 * But there is corner case, see the comment in ->post_xol().
661 */
666 }
670 }
673 {
680 }
683 {
685 /*
686 * We can only get here if branch_emulate_op() failed to push the ret
687 * address _and_ another thread expanded our stack before the (mangled)
688 * "call" insn was executed out-of-line. Just restore ->sp and restart.
689 * We could also restore ->ip and try to call branch_emulate_op() again.
690 */
693 }
696 {
697 /*
698 * Turn this insn into "call 1f; 1:", this is what we will execute
699 * out-of-line if ->emulate() fails. We only need this to generate
700 * a trap, so that the probed task receives the correct signal with
701 * the properly filled siginfo.
702 *
703 * But see the comment in ->post_xol(), in the unlikely case it can
704 * succeed. So we need to ensure that the new ->ip can not fall into
705 * the non-canonical area and trigger #GP.
706 *
707 * We could turn it into (say) "pushf", but then we would need to
708 * divorce ->insn[] and ->ixol[]. We need to preserve the 1st byte
709 * of ->insn[] for set_orig_insn().
710 */
713 }
718 };
722 };
724 /* Returns -ENOSYS if branch_xol_ops doesn't handle this insn */
726 {
743 /*
744 * If it is a "near" conditional jmp, OPCODE2() - 0x10 matches
745 * OPCODE1() of the "short" jmp which checks the same condition.
746 */
751 }
753 /*
754 * 16-bit overrides such as CALLW (66 e8 nn nn) are not supported.
755 * Intel and AMD behavior differ in 64-bit mode: Intel ignores 66 prefix.
756 * No one uses these insns, reject any branch insns with such prefix.
757 */
761 }
769 }
771 /* Returns -ENOSYS if push_xol_ops doesn't handle this insn */
773 {
782 /* only support rex_prefix 0x41 (x64 only) */
783 #ifdef CONFIG_X86_64
813 }
814 #else
816 #endif
843 }
844 }
850 }
852 /**
853 * arch_uprobe_analyze_insn - instruction analysis including validity and fixups.
854 * @mm: the probed address space.
855 * @arch_uprobe: the probepoint information.
856 * @addr: virtual address at which to install the probepoint
857 * Return 0 on success or a -ve number on error.
858 */
859 int arch_uprobe_analyze_insn(struct arch_uprobe *auprobe, struct mm_struct *mm, unsigned long addr)
860 {
877 /*
878 * Figure out which fixups default_post_xol_op() will need to perform,
879 * and annotate defparam->fixups accordingly.
880 */
903 }
904 /* fall through */
907 }
914 }
916 /*
917 * arch_uprobe_pre_xol - prepare to execute out of line.
918 * @auprobe: the probepoint information.
919 * @regs: reflects the saved user state of current task.
920 */
922 {
929 }
941 }
943 /*
944 * If xol insn itself traps and generates a signal(Say,
945 * SIGILL/SIGSEGV/etc), then detect the case where a singlestepped
946 * instruction jumps back to its own address. It is assumed that anything
947 * like do_page_fault/do_trap/etc sets thread.trap_nr != -1.
948 *
949 * arch_uprobe_pre_xol/arch_uprobe_post_xol save/restore thread.trap_nr,
950 * arch_uprobe_xol_was_trapped() simply checks that ->trap_nr is not equal to
951 * UPROBE_TRAP_NR == -1 set by arch_uprobe_pre_xol().
952 */
954 {
959 }
961 /*
962 * Called after single-stepping. To avoid the SMP problems that can
963 * occur when we temporarily put back the original opcode to
964 * single-step, we single-stepped a copy of the instruction.
965 *
966 * This function prepares to resume execution after the single-step.
967 */
969 {
980 /*
981 * Restore ->ip for restart or post mortem analysis.
982 * ->post_xol() must not return -ERESTART unless this
983 * is really possible.
984 */
989 }
990 }
991 /*
992 * arch_uprobe_pre_xol() doesn't save the state of TIF_BLOCKSTEP
993 * so we can get an extra SIGTRAP if we do not clear TF. We need
994 * to examine the opcode to make it right.
995 */
1003 }
1005 /* callback routine for handling exceptions. */
1007 {
1012 /* We are only interested in userspace traps */
1029 }
1032 }
1034 /*
1035 * This function gets called when XOL instruction either gets trapped or
1036 * the thread has a fatal signal. Reset the instruction pointer to its
1037 * probed address for the potential restart or for post mortem analysis.
1038 */
1040 {
1048 /* clear TF if it was set by us in arch_uprobe_pre_xol() */
1051 }
1054 {
1058 }
1061 {
1066 }
1068 unsigned long
1070 {
1077 /* check whether address has been already hijacked */
1090 }
1093 }
1097 {
1100 else
1102 }