linux/arch/x86/kernel/alternative.c
Linus Torvalds 902861e34c - Sumanth Korikkar has taught s390 to allocate hotplug-time page frames
from hotplugged memory rather than only from main memory.  Series
   "implement "memmap on memory" feature on s390".
 
 - More folio conversions from Matthew Wilcox in the series
 
 	"Convert memcontrol charge moving to use folios"
 	"mm: convert mm counter to take a folio"
 
 - Chengming Zhou has optimized zswap's rbtree locking, providing
   significant reductions in system time and modest but measurable
   reductions in overall runtimes.  The series is "mm/zswap: optimize the
   scalability of zswap rb-tree".
 
 - Chengming Zhou has also provided the series "mm/zswap: optimize zswap
   lru list" which provides measurable runtime benefits in some
   swap-intensive situations.
 
 - And Chengming Zhou further optimizes zswap in the series "mm/zswap:
   optimize for dynamic zswap_pools".  Measured improvements are modest.
 
 - zswap cleanups and simplifications from Yosry Ahmed in the series "mm:
   zswap: simplify zswap_swapoff()".
 
 - In the series "Add DAX ABI for memmap_on_memory", Vishal Verma has
   contributed several DAX cleanups as well as adding a sysfs tunable to
   control the memmap_on_memory setting when the dax device is hotplugged
   as system memory.
 
 - Johannes Weiner has added the large series "mm: zswap: cleanups",
   which does that.
 
 - More DAMON work from SeongJae Park in the series
 
 	"mm/damon: make DAMON debugfs interface deprecation unignorable"
 	"selftests/damon: add more tests for core functionalities and corner cases"
 	"Docs/mm/damon: misc readability improvements"
 	"mm/damon: let DAMOS feeds and tame/auto-tune itself"
 
 - In the series "mm/mempolicy: weighted interleave mempolicy and sysfs
   extension" Rakie Kim has developed a new mempolicy interleaving policy
   wherein we allocate memory across nodes in a weighted fashion rather
   than uniformly.  This is beneficial in heterogeneous memory environments
   appearing with CXL.
 
 - Christophe Leroy has contributed some cleanup and consolidation work
   against the ARM pagetable dumping code in the series "mm: ptdump:
   Refactor CONFIG_DEBUG_WX and check_wx_pages debugfs attribute".
 
 - Luis Chamberlain has added some additional xarray selftesting in the
   series "test_xarray: advanced API multi-index tests".
 
 - Muhammad Usama Anjum has reworked the selftest code to make its
   human-readable output conform to the TAP ("Test Anything Protocol")
   format.  Amongst other things, this opens up the use of third-party
   tools to parse and process out selftesting results.
 
 - Ryan Roberts has added fork()-time PTE batching of THP ptes in the
   series "mm/memory: optimize fork() with PTE-mapped THP".  Mainly
   targeted at arm64, this significantly speeds up fork() when the process
   has a large number of pte-mapped folios.
 
 - David Hildenbrand also gets in on the THP pte batching game in his
   series "mm/memory: optimize unmap/zap with PTE-mapped THP".  It
   implements batching during munmap() and other pte teardown situations.
   The microbenchmark improvements are nice.
 
 - And in the series "Transparent Contiguous PTEs for User Mappings" Ryan
   Roberts further utilizes arm's pte's contiguous bit ("contpte
   mappings").  Kernel build times on arm64 improved nicely.  Ryan's series
   "Address some contpte nits" provides some followup work.
 
 - In the series "mm/hugetlb: Restore the reservation" Breno Leitao has
   fixed an obscure hugetlb race which was causing unnecessary page faults.
   He has also added a reproducer under the selftest code.
 
 - In the series "selftests/mm: Output cleanups for the compaction test",
   Mark Brown did what the title claims.
 
 - Kinsey Ho has added the series "mm/mglru: code cleanup and refactoring".
 
 - Even more zswap material from Nhat Pham.  The series "fix and extend
   zswap kselftests" does as claimed.
 
 - In the series "Introduce cpu_dcache_is_aliasing() to fix DAX
   regression" Mathieu Desnoyers has cleaned up and fixed rather a mess in
   our handling of DAX on archiecctures which have virtually aliasing data
   caches.  The arm architecture is the main beneficiary.
 
 - Lokesh Gidra's series "per-vma locks in userfaultfd" provides dramatic
   improvements in worst-case mmap_lock hold times during certain
   userfaultfd operations.
 
 - Some page_owner enhancements and maintenance work from Oscar Salvador
   in his series
 
 	"page_owner: print stacks and their outstanding allocations"
 	"page_owner: Fixup and cleanup"
 
 - Uladzislau Rezki has contributed some vmalloc scalability improvements
   in his series "Mitigate a vmap lock contention".  It realizes a 12x
   improvement for a certain microbenchmark.
 
 - Some kexec/crash cleanup work from Baoquan He in the series "Split
   crash out from kexec and clean up related config items".
 
 - Some zsmalloc maintenance work from Chengming Zhou in the series
 
 	"mm/zsmalloc: fix and optimize objects/page migration"
 	"mm/zsmalloc: some cleanup for get/set_zspage_mapping()"
 
 - Zi Yan has taught the MM to perform compaction on folios larger than
   order=0.  This a step along the path to implementaton of the merging of
   large anonymous folios.  The series is named "Enable >0 order folio
   memory compaction".
 
 - Christoph Hellwig has done quite a lot of cleanup work in the
   pagecache writeback code in his series "convert write_cache_pages() to
   an iterator".
 
 - Some modest hugetlb cleanups and speedups in Vishal Moola's series
   "Handle hugetlb faults under the VMA lock".
 
 - Zi Yan has changed the page splitting code so we can split huge pages
   into sizes other than order-0 to better utilize large folios.  The
   series is named "Split a folio to any lower order folios".
 
 - David Hildenbrand has contributed the series "mm: remove
   total_mapcount()", a cleanup.
 
 - Matthew Wilcox has sought to improve the performance of bulk memory
   freeing in his series "Rearrange batched folio freeing".
 
 - Gang Li's series "hugetlb: parallelize hugetlb page init on boot"
   provides large improvements in bootup times on large machines which are
   configured to use large numbers of hugetlb pages.
 
 - Matthew Wilcox's series "PageFlags cleanups" does that.
 
 - Qi Zheng's series "minor fixes and supplement for ptdesc" does that
   also.  S390 is affected.
 
 - Cleanups to our pagemap utility functions from Peter Xu in his series
   "mm/treewide: Replace pXd_large() with pXd_leaf()".
 
 - Nico Pache has fixed a few things with our hugepage selftests in his
   series "selftests/mm: Improve Hugepage Test Handling in MM Selftests".
 
 - Also, of course, many singleton patches to many things.  Please see
   the individual changelogs for details.
 -----BEGIN PGP SIGNATURE-----
 
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 joxeAP9TrcMEuHnLmBlhIXkWbIR4+ki+pA3v+gNTlJiBhnfVSgD9G55t1aBaRplx
 TMNhHfyiHYDTx/GAV9NXW84tasJSDgA=
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Merge tag 'mm-stable-2024-03-13-20-04' of git://git.kernel.org/pub/scm/linux/kernel/git/akpm/mm

Pull MM updates from Andrew Morton:

 - Sumanth Korikkar has taught s390 to allocate hotplug-time page frames
   from hotplugged memory rather than only from main memory. Series
   "implement "memmap on memory" feature on s390".

 - More folio conversions from Matthew Wilcox in the series

	"Convert memcontrol charge moving to use folios"
	"mm: convert mm counter to take a folio"

 - Chengming Zhou has optimized zswap's rbtree locking, providing
   significant reductions in system time and modest but measurable
   reductions in overall runtimes. The series is "mm/zswap: optimize the
   scalability of zswap rb-tree".

 - Chengming Zhou has also provided the series "mm/zswap: optimize zswap
   lru list" which provides measurable runtime benefits in some
   swap-intensive situations.

 - And Chengming Zhou further optimizes zswap in the series "mm/zswap:
   optimize for dynamic zswap_pools". Measured improvements are modest.

 - zswap cleanups and simplifications from Yosry Ahmed in the series
   "mm: zswap: simplify zswap_swapoff()".

 - In the series "Add DAX ABI for memmap_on_memory", Vishal Verma has
   contributed several DAX cleanups as well as adding a sysfs tunable to
   control the memmap_on_memory setting when the dax device is
   hotplugged as system memory.

 - Johannes Weiner has added the large series "mm: zswap: cleanups",
   which does that.

 - More DAMON work from SeongJae Park in the series

	"mm/damon: make DAMON debugfs interface deprecation unignorable"
	"selftests/damon: add more tests for core functionalities and corner cases"
	"Docs/mm/damon: misc readability improvements"
	"mm/damon: let DAMOS feeds and tame/auto-tune itself"

 - In the series "mm/mempolicy: weighted interleave mempolicy and sysfs
   extension" Rakie Kim has developed a new mempolicy interleaving
   policy wherein we allocate memory across nodes in a weighted fashion
   rather than uniformly. This is beneficial in heterogeneous memory
   environments appearing with CXL.

 - Christophe Leroy has contributed some cleanup and consolidation work
   against the ARM pagetable dumping code in the series "mm: ptdump:
   Refactor CONFIG_DEBUG_WX and check_wx_pages debugfs attribute".

 - Luis Chamberlain has added some additional xarray selftesting in the
   series "test_xarray: advanced API multi-index tests".

 - Muhammad Usama Anjum has reworked the selftest code to make its
   human-readable output conform to the TAP ("Test Anything Protocol")
   format. Amongst other things, this opens up the use of third-party
   tools to parse and process out selftesting results.

 - Ryan Roberts has added fork()-time PTE batching of THP ptes in the
   series "mm/memory: optimize fork() with PTE-mapped THP". Mainly
   targeted at arm64, this significantly speeds up fork() when the
   process has a large number of pte-mapped folios.

 - David Hildenbrand also gets in on the THP pte batching game in his
   series "mm/memory: optimize unmap/zap with PTE-mapped THP". It
   implements batching during munmap() and other pte teardown
   situations. The microbenchmark improvements are nice.

 - And in the series "Transparent Contiguous PTEs for User Mappings"
   Ryan Roberts further utilizes arm's pte's contiguous bit ("contpte
   mappings"). Kernel build times on arm64 improved nicely. Ryan's
   series "Address some contpte nits" provides some followup work.

 - In the series "mm/hugetlb: Restore the reservation" Breno Leitao has
   fixed an obscure hugetlb race which was causing unnecessary page
   faults. He has also added a reproducer under the selftest code.

 - In the series "selftests/mm: Output cleanups for the compaction
   test", Mark Brown did what the title claims.

 - Kinsey Ho has added the series "mm/mglru: code cleanup and
   refactoring".

 - Even more zswap material from Nhat Pham. The series "fix and extend
   zswap kselftests" does as claimed.

 - In the series "Introduce cpu_dcache_is_aliasing() to fix DAX
   regression" Mathieu Desnoyers has cleaned up and fixed rather a mess
   in our handling of DAX on archiecctures which have virtually aliasing
   data caches. The arm architecture is the main beneficiary.

 - Lokesh Gidra's series "per-vma locks in userfaultfd" provides
   dramatic improvements in worst-case mmap_lock hold times during
   certain userfaultfd operations.

 - Some page_owner enhancements and maintenance work from Oscar Salvador
   in his series

	"page_owner: print stacks and their outstanding allocations"
	"page_owner: Fixup and cleanup"

 - Uladzislau Rezki has contributed some vmalloc scalability
   improvements in his series "Mitigate a vmap lock contention". It
   realizes a 12x improvement for a certain microbenchmark.

 - Some kexec/crash cleanup work from Baoquan He in the series "Split
   crash out from kexec and clean up related config items".

 - Some zsmalloc maintenance work from Chengming Zhou in the series

	"mm/zsmalloc: fix and optimize objects/page migration"
	"mm/zsmalloc: some cleanup for get/set_zspage_mapping()"

 - Zi Yan has taught the MM to perform compaction on folios larger than
   order=0. This a step along the path to implementaton of the merging
   of large anonymous folios. The series is named "Enable >0 order folio
   memory compaction".

 - Christoph Hellwig has done quite a lot of cleanup work in the
   pagecache writeback code in his series "convert write_cache_pages()
   to an iterator".

 - Some modest hugetlb cleanups and speedups in Vishal Moola's series
   "Handle hugetlb faults under the VMA lock".

 - Zi Yan has changed the page splitting code so we can split huge pages
   into sizes other than order-0 to better utilize large folios. The
   series is named "Split a folio to any lower order folios".

 - David Hildenbrand has contributed the series "mm: remove
   total_mapcount()", a cleanup.

 - Matthew Wilcox has sought to improve the performance of bulk memory
   freeing in his series "Rearrange batched folio freeing".

 - Gang Li's series "hugetlb: parallelize hugetlb page init on boot"
   provides large improvements in bootup times on large machines which
   are configured to use large numbers of hugetlb pages.

 - Matthew Wilcox's series "PageFlags cleanups" does that.

 - Qi Zheng's series "minor fixes and supplement for ptdesc" does that
   also. S390 is affected.

 - Cleanups to our pagemap utility functions from Peter Xu in his series
   "mm/treewide: Replace pXd_large() with pXd_leaf()".

 - Nico Pache has fixed a few things with our hugepage selftests in his
   series "selftests/mm: Improve Hugepage Test Handling in MM
   Selftests".

 - Also, of course, many singleton patches to many things. Please see
   the individual changelogs for details.

* tag 'mm-stable-2024-03-13-20-04' of git://git.kernel.org/pub/scm/linux/kernel/git/akpm/mm: (435 commits)
  mm/zswap: remove the memcpy if acomp is not sleepable
  crypto: introduce: acomp_is_async to expose if comp drivers might sleep
  memtest: use {READ,WRITE}_ONCE in memory scanning
  mm: prohibit the last subpage from reusing the entire large folio
  mm: recover pud_leaf() definitions in nopmd case
  selftests/mm: skip the hugetlb-madvise tests on unmet hugepage requirements
  selftests/mm: skip uffd hugetlb tests with insufficient hugepages
  selftests/mm: dont fail testsuite due to a lack of hugepages
  mm/huge_memory: skip invalid debugfs new_order input for folio split
  mm/huge_memory: check new folio order when split a folio
  mm, vmscan: retry kswapd's priority loop with cache_trim_mode off on failure
  mm: add an explicit smp_wmb() to UFFDIO_CONTINUE
  mm: fix list corruption in put_pages_list
  mm: remove folio from deferred split list before uncharging it
  filemap: avoid unnecessary major faults in filemap_fault()
  mm,page_owner: drop unnecessary check
  mm,page_owner: check for null stack_record before bumping its refcount
  mm: swap: fix race between free_swap_and_cache() and swapoff()
  mm/treewide: align up pXd_leaf() retval across archs
  mm/treewide: drop pXd_large()
  ...
2024-03-14 17:43:30 -07:00

2525 lines
60 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
#define pr_fmt(fmt) "SMP alternatives: " fmt
#include <linux/module.h>
#include <linux/sched.h>
#include <linux/perf_event.h>
#include <linux/mutex.h>
#include <linux/list.h>
#include <linux/stringify.h>
#include <linux/highmem.h>
#include <linux/mm.h>
#include <linux/vmalloc.h>
#include <linux/memory.h>
#include <linux/stop_machine.h>
#include <linux/slab.h>
#include <linux/kdebug.h>
#include <linux/kprobes.h>
#include <linux/mmu_context.h>
#include <linux/bsearch.h>
#include <linux/sync_core.h>
#include <asm/text-patching.h>
#include <asm/alternative.h>
#include <asm/sections.h>
#include <asm/mce.h>
#include <asm/nmi.h>
#include <asm/cacheflush.h>
#include <asm/tlbflush.h>
#include <asm/insn.h>
#include <asm/io.h>
#include <asm/fixmap.h>
#include <asm/paravirt.h>
#include <asm/asm-prototypes.h>
#include <asm/cfi.h>
int __read_mostly alternatives_patched;
EXPORT_SYMBOL_GPL(alternatives_patched);
#define MAX_PATCH_LEN (255-1)
#define DA_ALL (~0)
#define DA_ALT 0x01
#define DA_RET 0x02
#define DA_RETPOLINE 0x04
#define DA_ENDBR 0x08
#define DA_SMP 0x10
static unsigned int debug_alternative;
static int __init debug_alt(char *str)
{
if (str && *str == '=')
str++;
if (!str || kstrtouint(str, 0, &debug_alternative))
debug_alternative = DA_ALL;
return 1;
}
__setup("debug-alternative", debug_alt);
static int noreplace_smp;
static int __init setup_noreplace_smp(char *str)
{
noreplace_smp = 1;
return 1;
}
__setup("noreplace-smp", setup_noreplace_smp);
#define DPRINTK(type, fmt, args...) \
do { \
if (debug_alternative & DA_##type) \
printk(KERN_DEBUG pr_fmt(fmt) "\n", ##args); \
} while (0)
#define DUMP_BYTES(type, buf, len, fmt, args...) \
do { \
if (unlikely(debug_alternative & DA_##type)) { \
int j; \
\
if (!(len)) \
break; \
\
printk(KERN_DEBUG pr_fmt(fmt), ##args); \
for (j = 0; j < (len) - 1; j++) \
printk(KERN_CONT "%02hhx ", buf[j]); \
printk(KERN_CONT "%02hhx\n", buf[j]); \
} \
} while (0)
static const unsigned char x86nops[] =
{
BYTES_NOP1,
BYTES_NOP2,
BYTES_NOP3,
BYTES_NOP4,
BYTES_NOP5,
BYTES_NOP6,
BYTES_NOP7,
BYTES_NOP8,
#ifdef CONFIG_64BIT
BYTES_NOP9,
BYTES_NOP10,
BYTES_NOP11,
#endif
};
const unsigned char * const x86_nops[ASM_NOP_MAX+1] =
{
NULL,
x86nops,
x86nops + 1,
x86nops + 1 + 2,
x86nops + 1 + 2 + 3,
x86nops + 1 + 2 + 3 + 4,
x86nops + 1 + 2 + 3 + 4 + 5,
x86nops + 1 + 2 + 3 + 4 + 5 + 6,
x86nops + 1 + 2 + 3 + 4 + 5 + 6 + 7,
#ifdef CONFIG_64BIT
x86nops + 1 + 2 + 3 + 4 + 5 + 6 + 7 + 8,
x86nops + 1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9,
x86nops + 1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 + 10,
#endif
};
/*
* Fill the buffer with a single effective instruction of size @len.
*
* In order not to issue an ORC stack depth tracking CFI entry (Call Frame Info)
* for every single-byte NOP, try to generate the maximally available NOP of
* size <= ASM_NOP_MAX such that only a single CFI entry is generated (vs one for
* each single-byte NOPs). If @len to fill out is > ASM_NOP_MAX, pad with INT3 and
* *jump* over instead of executing long and daft NOPs.
*/
static void add_nop(u8 *instr, unsigned int len)
{
u8 *target = instr + len;
if (!len)
return;
if (len <= ASM_NOP_MAX) {
memcpy(instr, x86_nops[len], len);
return;
}
if (len < 128) {
__text_gen_insn(instr, JMP8_INSN_OPCODE, instr, target, JMP8_INSN_SIZE);
instr += JMP8_INSN_SIZE;
} else {
__text_gen_insn(instr, JMP32_INSN_OPCODE, instr, target, JMP32_INSN_SIZE);
instr += JMP32_INSN_SIZE;
}
for (;instr < target; instr++)
*instr = INT3_INSN_OPCODE;
}
extern s32 __retpoline_sites[], __retpoline_sites_end[];
extern s32 __return_sites[], __return_sites_end[];
extern s32 __cfi_sites[], __cfi_sites_end[];
extern s32 __ibt_endbr_seal[], __ibt_endbr_seal_end[];
extern s32 __smp_locks[], __smp_locks_end[];
void text_poke_early(void *addr, const void *opcode, size_t len);
/*
* Matches NOP and NOPL, not any of the other possible NOPs.
*/
static bool insn_is_nop(struct insn *insn)
{
/* Anything NOP, but no REP NOP */
if (insn->opcode.bytes[0] == 0x90 &&
(!insn->prefixes.nbytes || insn->prefixes.bytes[0] != 0xF3))
return true;
/* NOPL */
if (insn->opcode.bytes[0] == 0x0F && insn->opcode.bytes[1] == 0x1F)
return true;
/* TODO: more nops */
return false;
}
/*
* Find the offset of the first non-NOP instruction starting at @offset
* but no further than @len.
*/
static int skip_nops(u8 *instr, int offset, int len)
{
struct insn insn;
for (; offset < len; offset += insn.length) {
if (insn_decode_kernel(&insn, &instr[offset]))
break;
if (!insn_is_nop(&insn))
break;
}
return offset;
}
/*
* Optimize a sequence of NOPs, possibly preceded by an unconditional jump
* to the end of the NOP sequence into a single NOP.
*/
static bool
__optimize_nops(u8 *instr, size_t len, struct insn *insn, int *next, int *prev, int *target)
{
int i = *next - insn->length;
switch (insn->opcode.bytes[0]) {
case JMP8_INSN_OPCODE:
case JMP32_INSN_OPCODE:
*prev = i;
*target = *next + insn->immediate.value;
return false;
}
if (insn_is_nop(insn)) {
int nop = i;
*next = skip_nops(instr, *next, len);
if (*target && *next == *target)
nop = *prev;
add_nop(instr + nop, *next - nop);
DUMP_BYTES(ALT, instr, len, "%px: [%d:%d) optimized NOPs: ", instr, nop, *next);
return true;
}
*target = 0;
return false;
}
/*
* "noinline" to cause control flow change and thus invalidate I$ and
* cause refetch after modification.
*/
static void __init_or_module noinline optimize_nops(u8 *instr, size_t len)
{
int prev, target = 0;
for (int next, i = 0; i < len; i = next) {
struct insn insn;
if (insn_decode_kernel(&insn, &instr[i]))
return;
next = i + insn.length;
__optimize_nops(instr, len, &insn, &next, &prev, &target);
}
}
static void __init_or_module noinline optimize_nops_inplace(u8 *instr, size_t len)
{
unsigned long flags;
local_irq_save(flags);
optimize_nops(instr, len);
sync_core();
local_irq_restore(flags);
}
/*
* In this context, "source" is where the instructions are placed in the
* section .altinstr_replacement, for example during kernel build by the
* toolchain.
* "Destination" is where the instructions are being patched in by this
* machinery.
*
* The source offset is:
*
* src_imm = target - src_next_ip (1)
*
* and the target offset is:
*
* dst_imm = target - dst_next_ip (2)
*
* so rework (1) as an expression for target like:
*
* target = src_imm + src_next_ip (1a)
*
* and substitute in (2) to get:
*
* dst_imm = (src_imm + src_next_ip) - dst_next_ip (3)
*
* Now, since the instruction stream is 'identical' at src and dst (it
* is being copied after all) it can be stated that:
*
* src_next_ip = src + ip_offset
* dst_next_ip = dst + ip_offset (4)
*
* Substitute (4) in (3) and observe ip_offset being cancelled out to
* obtain:
*
* dst_imm = src_imm + (src + ip_offset) - (dst + ip_offset)
* = src_imm + src - dst + ip_offset - ip_offset
* = src_imm + src - dst (5)
*
* IOW, only the relative displacement of the code block matters.
*/
#define apply_reloc_n(n_, p_, d_) \
do { \
s32 v = *(s##n_ *)(p_); \
v += (d_); \
BUG_ON((v >> 31) != (v >> (n_-1))); \
*(s##n_ *)(p_) = (s##n_)v; \
} while (0)
static __always_inline
void apply_reloc(int n, void *ptr, uintptr_t diff)
{
switch (n) {
case 1: apply_reloc_n(8, ptr, diff); break;
case 2: apply_reloc_n(16, ptr, diff); break;
case 4: apply_reloc_n(32, ptr, diff); break;
default: BUG();
}
}
static __always_inline
bool need_reloc(unsigned long offset, u8 *src, size_t src_len)
{
u8 *target = src + offset;
/*
* If the target is inside the patched block, it's relative to the
* block itself and does not need relocation.
*/
return (target < src || target > src + src_len);
}
void apply_relocation(u8 *buf, size_t len, u8 *dest, u8 *src, size_t src_len)
{
int prev, target = 0;
for (int next, i = 0; i < len; i = next) {
struct insn insn;
if (WARN_ON_ONCE(insn_decode_kernel(&insn, &buf[i])))
return;
next = i + insn.length;
if (__optimize_nops(buf, len, &insn, &next, &prev, &target))
continue;
switch (insn.opcode.bytes[0]) {
case 0x0f:
if (insn.opcode.bytes[1] < 0x80 ||
insn.opcode.bytes[1] > 0x8f)
break;
fallthrough; /* Jcc.d32 */
case 0x70 ... 0x7f: /* Jcc.d8 */
case JMP8_INSN_OPCODE:
case JMP32_INSN_OPCODE:
case CALL_INSN_OPCODE:
if (need_reloc(next + insn.immediate.value, src, src_len)) {
apply_reloc(insn.immediate.nbytes,
buf + i + insn_offset_immediate(&insn),
src - dest);
}
/*
* Where possible, convert JMP.d32 into JMP.d8.
*/
if (insn.opcode.bytes[0] == JMP32_INSN_OPCODE) {
s32 imm = insn.immediate.value;
imm += src - dest;
imm += JMP32_INSN_SIZE - JMP8_INSN_SIZE;
if ((imm >> 31) == (imm >> 7)) {
buf[i+0] = JMP8_INSN_OPCODE;
buf[i+1] = (s8)imm;
memset(&buf[i+2], INT3_INSN_OPCODE, insn.length - 2);
}
}
break;
}
if (insn_rip_relative(&insn)) {
if (need_reloc(next + insn.displacement.value, src, src_len)) {
apply_reloc(insn.displacement.nbytes,
buf + i + insn_offset_displacement(&insn),
src - dest);
}
}
}
}
/* Low-level backend functions usable from alternative code replacements. */
DEFINE_ASM_FUNC(nop_func, "", .entry.text);
EXPORT_SYMBOL_GPL(nop_func);
noinstr void BUG_func(void)
{
BUG();
}
EXPORT_SYMBOL(BUG_func);
#define CALL_RIP_REL_OPCODE 0xff
#define CALL_RIP_REL_MODRM 0x15
/*
* Rewrite the "call BUG_func" replacement to point to the target of the
* indirect pv_ops call "call *disp(%ip)".
*/
static int alt_replace_call(u8 *instr, u8 *insn_buff, struct alt_instr *a)
{
void *target, *bug = &BUG_func;
s32 disp;
if (a->replacementlen != 5 || insn_buff[0] != CALL_INSN_OPCODE) {
pr_err("ALT_FLAG_DIRECT_CALL set for a non-call replacement instruction\n");
BUG();
}
if (a->instrlen != 6 ||
instr[0] != CALL_RIP_REL_OPCODE ||
instr[1] != CALL_RIP_REL_MODRM) {
pr_err("ALT_FLAG_DIRECT_CALL set for unrecognized indirect call\n");
BUG();
}
/* Skip CALL_RIP_REL_OPCODE and CALL_RIP_REL_MODRM */
disp = *(s32 *)(instr + 2);
#ifdef CONFIG_X86_64
/* ff 15 00 00 00 00 call *0x0(%rip) */
/* target address is stored at "next instruction + disp". */
target = *(void **)(instr + a->instrlen + disp);
#else
/* ff 15 00 00 00 00 call *0x0 */
/* target address is stored at disp. */
target = *(void **)disp;
#endif
if (!target)
target = bug;
/* (BUG_func - .) + (target - BUG_func) := target - . */
*(s32 *)(insn_buff + 1) += target - bug;
if (target == &nop_func)
return 0;
return 5;
}
/*
* Replace instructions with better alternatives for this CPU type. This runs
* before SMP is initialized to avoid SMP problems with self modifying code.
* This implies that asymmetric systems where APs have less capabilities than
* the boot processor are not handled. Tough. Make sure you disable such
* features by hand.
*
* Marked "noinline" to cause control flow change and thus insn cache
* to refetch changed I$ lines.
*/
void __init_or_module noinline apply_alternatives(struct alt_instr *start,
struct alt_instr *end)
{
struct alt_instr *a;
u8 *instr, *replacement;
u8 insn_buff[MAX_PATCH_LEN];
DPRINTK(ALT, "alt table %px, -> %px", start, end);
/*
* In the case CONFIG_X86_5LEVEL=y, KASAN_SHADOW_START is defined using
* cpu_feature_enabled(X86_FEATURE_LA57) and is therefore patched here.
* During the process, KASAN becomes confused seeing partial LA57
* conversion and triggers a false-positive out-of-bound report.
*
* Disable KASAN until the patching is complete.
*/
kasan_disable_current();
/*
* The scan order should be from start to end. A later scanned
* alternative code can overwrite previously scanned alternative code.
* Some kernel functions (e.g. memcpy, memset, etc) use this order to
* patch code.
*
* So be careful if you want to change the scan order to any other
* order.
*/
for (a = start; a < end; a++) {
int insn_buff_sz = 0;
instr = (u8 *)&a->instr_offset + a->instr_offset;
replacement = (u8 *)&a->repl_offset + a->repl_offset;
BUG_ON(a->instrlen > sizeof(insn_buff));
BUG_ON(a->cpuid >= (NCAPINTS + NBUGINTS) * 32);
/*
* Patch if either:
* - feature is present
* - feature not present but ALT_FLAG_NOT is set to mean,
* patch if feature is *NOT* present.
*/
if (!boot_cpu_has(a->cpuid) == !(a->flags & ALT_FLAG_NOT)) {
optimize_nops_inplace(instr, a->instrlen);
continue;
}
DPRINTK(ALT, "feat: %d*32+%d, old: (%pS (%px) len: %d), repl: (%px, len: %d) flags: 0x%x",
a->cpuid >> 5,
a->cpuid & 0x1f,
instr, instr, a->instrlen,
replacement, a->replacementlen, a->flags);
memcpy(insn_buff, replacement, a->replacementlen);
insn_buff_sz = a->replacementlen;
if (a->flags & ALT_FLAG_DIRECT_CALL) {
insn_buff_sz = alt_replace_call(instr, insn_buff, a);
if (insn_buff_sz < 0)
continue;
}
for (; insn_buff_sz < a->instrlen; insn_buff_sz++)
insn_buff[insn_buff_sz] = 0x90;
apply_relocation(insn_buff, a->instrlen, instr, replacement, a->replacementlen);
DUMP_BYTES(ALT, instr, a->instrlen, "%px: old_insn: ", instr);
DUMP_BYTES(ALT, replacement, a->replacementlen, "%px: rpl_insn: ", replacement);
DUMP_BYTES(ALT, insn_buff, insn_buff_sz, "%px: final_insn: ", instr);
text_poke_early(instr, insn_buff, insn_buff_sz);
}
kasan_enable_current();
}
static inline bool is_jcc32(struct insn *insn)
{
/* Jcc.d32 second opcode byte is in the range: 0x80-0x8f */
return insn->opcode.bytes[0] == 0x0f && (insn->opcode.bytes[1] & 0xf0) == 0x80;
}
#if defined(CONFIG_MITIGATION_RETPOLINE) && defined(CONFIG_OBJTOOL)
/*
* CALL/JMP *%\reg
*/
static int emit_indirect(int op, int reg, u8 *bytes)
{
int i = 0;
u8 modrm;
switch (op) {
case CALL_INSN_OPCODE:
modrm = 0x10; /* Reg = 2; CALL r/m */
break;
case JMP32_INSN_OPCODE:
modrm = 0x20; /* Reg = 4; JMP r/m */
break;
default:
WARN_ON_ONCE(1);
return -1;
}
if (reg >= 8) {
bytes[i++] = 0x41; /* REX.B prefix */
reg -= 8;
}
modrm |= 0xc0; /* Mod = 3 */
modrm += reg;
bytes[i++] = 0xff; /* opcode */
bytes[i++] = modrm;
return i;
}
static int emit_call_track_retpoline(void *addr, struct insn *insn, int reg, u8 *bytes)
{
u8 op = insn->opcode.bytes[0];
int i = 0;
/*
* Clang does 'weird' Jcc __x86_indirect_thunk_r11 conditional
* tail-calls. Deal with them.
*/
if (is_jcc32(insn)) {
bytes[i++] = op;
op = insn->opcode.bytes[1];
goto clang_jcc;
}
if (insn->length == 6)
bytes[i++] = 0x2e; /* CS-prefix */
switch (op) {
case CALL_INSN_OPCODE:
__text_gen_insn(bytes+i, op, addr+i,
__x86_indirect_call_thunk_array[reg],
CALL_INSN_SIZE);
i += CALL_INSN_SIZE;
break;
case JMP32_INSN_OPCODE:
clang_jcc:
__text_gen_insn(bytes+i, op, addr+i,
__x86_indirect_jump_thunk_array[reg],
JMP32_INSN_SIZE);
i += JMP32_INSN_SIZE;
break;
default:
WARN(1, "%pS %px %*ph\n", addr, addr, 6, addr);
return -1;
}
WARN_ON_ONCE(i != insn->length);
return i;
}
/*
* Rewrite the compiler generated retpoline thunk calls.
*
* For spectre_v2=off (!X86_FEATURE_RETPOLINE), rewrite them into immediate
* indirect instructions, avoiding the extra indirection.
*
* For example, convert:
*
* CALL __x86_indirect_thunk_\reg
*
* into:
*
* CALL *%\reg
*
* It also tries to inline spectre_v2=retpoline,lfence when size permits.
*/
static int patch_retpoline(void *addr, struct insn *insn, u8 *bytes)
{
retpoline_thunk_t *target;
int reg, ret, i = 0;
u8 op, cc;
target = addr + insn->length + insn->immediate.value;
reg = target - __x86_indirect_thunk_array;
if (WARN_ON_ONCE(reg & ~0xf))
return -1;
/* If anyone ever does: CALL/JMP *%rsp, we're in deep trouble. */
BUG_ON(reg == 4);
if (cpu_feature_enabled(X86_FEATURE_RETPOLINE) &&
!cpu_feature_enabled(X86_FEATURE_RETPOLINE_LFENCE)) {
if (cpu_feature_enabled(X86_FEATURE_CALL_DEPTH))
return emit_call_track_retpoline(addr, insn, reg, bytes);
return -1;
}
op = insn->opcode.bytes[0];
/*
* Convert:
*
* Jcc.d32 __x86_indirect_thunk_\reg
*
* into:
*
* Jncc.d8 1f
* [ LFENCE ]
* JMP *%\reg
* [ NOP ]
* 1:
*/
if (is_jcc32(insn)) {
cc = insn->opcode.bytes[1] & 0xf;
cc ^= 1; /* invert condition */
bytes[i++] = 0x70 + cc; /* Jcc.d8 */
bytes[i++] = insn->length - 2; /* sizeof(Jcc.d8) == 2 */
/* Continue as if: JMP.d32 __x86_indirect_thunk_\reg */
op = JMP32_INSN_OPCODE;
}
/*
* For RETPOLINE_LFENCE: prepend the indirect CALL/JMP with an LFENCE.
*/
if (cpu_feature_enabled(X86_FEATURE_RETPOLINE_LFENCE)) {
bytes[i++] = 0x0f;
bytes[i++] = 0xae;
bytes[i++] = 0xe8; /* LFENCE */
}
ret = emit_indirect(op, reg, bytes + i);
if (ret < 0)
return ret;
i += ret;
/*
* The compiler is supposed to EMIT an INT3 after every unconditional
* JMP instruction due to AMD BTC. However, if the compiler is too old
* or MITIGATION_SLS isn't enabled, we still need an INT3 after
* indirect JMPs even on Intel.
*/
if (op == JMP32_INSN_OPCODE && i < insn->length)
bytes[i++] = INT3_INSN_OPCODE;
for (; i < insn->length;)
bytes[i++] = BYTES_NOP1;
return i;
}
/*
* Generated by 'objtool --retpoline'.
*/
void __init_or_module noinline apply_retpolines(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
struct insn insn;
int len, ret;
u8 bytes[16];
u8 op1, op2;
ret = insn_decode_kernel(&insn, addr);
if (WARN_ON_ONCE(ret < 0))
continue;
op1 = insn.opcode.bytes[0];
op2 = insn.opcode.bytes[1];
switch (op1) {
case CALL_INSN_OPCODE:
case JMP32_INSN_OPCODE:
break;
case 0x0f: /* escape */
if (op2 >= 0x80 && op2 <= 0x8f)
break;
fallthrough;
default:
WARN_ON_ONCE(1);
continue;
}
DPRINTK(RETPOLINE, "retpoline at: %pS (%px) len: %d to: %pS",
addr, addr, insn.length,
addr + insn.length + insn.immediate.value);
len = patch_retpoline(addr, &insn, bytes);
if (len == insn.length) {
optimize_nops(bytes, len);
DUMP_BYTES(RETPOLINE, ((u8*)addr), len, "%px: orig: ", addr);
DUMP_BYTES(RETPOLINE, ((u8*)bytes), len, "%px: repl: ", addr);
text_poke_early(addr, bytes, len);
}
}
}
#ifdef CONFIG_MITIGATION_RETHUNK
/*
* Rewrite the compiler generated return thunk tail-calls.
*
* For example, convert:
*
* JMP __x86_return_thunk
*
* into:
*
* RET
*/
static int patch_return(void *addr, struct insn *insn, u8 *bytes)
{
int i = 0;
/* Patch the custom return thunks... */
if (cpu_feature_enabled(X86_FEATURE_RETHUNK)) {
i = JMP32_INSN_SIZE;
__text_gen_insn(bytes, JMP32_INSN_OPCODE, addr, x86_return_thunk, i);
} else {
/* ... or patch them out if not needed. */
bytes[i++] = RET_INSN_OPCODE;
}
for (; i < insn->length;)
bytes[i++] = INT3_INSN_OPCODE;
return i;
}
void __init_or_module noinline apply_returns(s32 *start, s32 *end)
{
s32 *s;
if (cpu_feature_enabled(X86_FEATURE_RETHUNK))
static_call_force_reinit();
for (s = start; s < end; s++) {
void *dest = NULL, *addr = (void *)s + *s;
struct insn insn;
int len, ret;
u8 bytes[16];
u8 op;
ret = insn_decode_kernel(&insn, addr);
if (WARN_ON_ONCE(ret < 0))
continue;
op = insn.opcode.bytes[0];
if (op == JMP32_INSN_OPCODE)
dest = addr + insn.length + insn.immediate.value;
if (__static_call_fixup(addr, op, dest) ||
WARN_ONCE(dest != &__x86_return_thunk,
"missing return thunk: %pS-%pS: %*ph",
addr, dest, 5, addr))
continue;
DPRINTK(RET, "return thunk at: %pS (%px) len: %d to: %pS",
addr, addr, insn.length,
addr + insn.length + insn.immediate.value);
len = patch_return(addr, &insn, bytes);
if (len == insn.length) {
DUMP_BYTES(RET, ((u8*)addr), len, "%px: orig: ", addr);
DUMP_BYTES(RET, ((u8*)bytes), len, "%px: repl: ", addr);
text_poke_early(addr, bytes, len);
}
}
}
#else
void __init_or_module noinline apply_returns(s32 *start, s32 *end) { }
#endif /* CONFIG_MITIGATION_RETHUNK */
#else /* !CONFIG_MITIGATION_RETPOLINE || !CONFIG_OBJTOOL */
void __init_or_module noinline apply_retpolines(s32 *start, s32 *end) { }
void __init_or_module noinline apply_returns(s32 *start, s32 *end) { }
#endif /* CONFIG_MITIGATION_RETPOLINE && CONFIG_OBJTOOL */
#ifdef CONFIG_X86_KERNEL_IBT
static void poison_cfi(void *addr);
static void __init_or_module poison_endbr(void *addr, bool warn)
{
u32 endbr, poison = gen_endbr_poison();
if (WARN_ON_ONCE(get_kernel_nofault(endbr, addr)))
return;
if (!is_endbr(endbr)) {
WARN_ON_ONCE(warn);
return;
}
DPRINTK(ENDBR, "ENDBR at: %pS (%px)", addr, addr);
/*
* When we have IBT, the lack of ENDBR will trigger #CP
*/
DUMP_BYTES(ENDBR, ((u8*)addr), 4, "%px: orig: ", addr);
DUMP_BYTES(ENDBR, ((u8*)&poison), 4, "%px: repl: ", addr);
text_poke_early(addr, &poison, 4);
}
/*
* Generated by: objtool --ibt
*
* Seal the functions for indirect calls by clobbering the ENDBR instructions
* and the kCFI hash value.
*/
void __init_or_module noinline apply_seal_endbr(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
poison_endbr(addr, true);
if (IS_ENABLED(CONFIG_FINEIBT))
poison_cfi(addr - 16);
}
}
#else
void __init_or_module apply_seal_endbr(s32 *start, s32 *end) { }
#endif /* CONFIG_X86_KERNEL_IBT */
#ifdef CONFIG_FINEIBT
#define __CFI_DEFAULT CFI_DEFAULT
#elif defined(CONFIG_CFI_CLANG)
#define __CFI_DEFAULT CFI_KCFI
#else
#define __CFI_DEFAULT CFI_OFF
#endif
enum cfi_mode cfi_mode __ro_after_init = __CFI_DEFAULT;
#ifdef CONFIG_CFI_CLANG
struct bpf_insn;
/* Must match bpf_func_t / DEFINE_BPF_PROG_RUN() */
extern unsigned int __bpf_prog_runX(const void *ctx,
const struct bpf_insn *insn);
/*
* Force a reference to the external symbol so the compiler generates
* __kcfi_typid.
*/
__ADDRESSABLE(__bpf_prog_runX);
/* u32 __ro_after_init cfi_bpf_hash = __kcfi_typeid___bpf_prog_runX; */
asm (
" .pushsection .data..ro_after_init,\"aw\",@progbits \n"
" .type cfi_bpf_hash,@object \n"
" .globl cfi_bpf_hash \n"
" .p2align 2, 0x0 \n"
"cfi_bpf_hash: \n"
" .long __kcfi_typeid___bpf_prog_runX \n"
" .size cfi_bpf_hash, 4 \n"
" .popsection \n"
);
/* Must match bpf_callback_t */
extern u64 __bpf_callback_fn(u64, u64, u64, u64, u64);
__ADDRESSABLE(__bpf_callback_fn);
/* u32 __ro_after_init cfi_bpf_subprog_hash = __kcfi_typeid___bpf_callback_fn; */
asm (
" .pushsection .data..ro_after_init,\"aw\",@progbits \n"
" .type cfi_bpf_subprog_hash,@object \n"
" .globl cfi_bpf_subprog_hash \n"
" .p2align 2, 0x0 \n"
"cfi_bpf_subprog_hash: \n"
" .long __kcfi_typeid___bpf_callback_fn \n"
" .size cfi_bpf_subprog_hash, 4 \n"
" .popsection \n"
);
u32 cfi_get_func_hash(void *func)
{
u32 hash;
func -= cfi_get_offset();
switch (cfi_mode) {
case CFI_FINEIBT:
func += 7;
break;
case CFI_KCFI:
func += 1;
break;
default:
return 0;
}
if (get_kernel_nofault(hash, func))
return 0;
return hash;
}
#endif
#ifdef CONFIG_FINEIBT
static bool cfi_rand __ro_after_init = true;
static u32 cfi_seed __ro_after_init;
/*
* Re-hash the CFI hash with a boot-time seed while making sure the result is
* not a valid ENDBR instruction.
*/
static u32 cfi_rehash(u32 hash)
{
hash ^= cfi_seed;
while (unlikely(is_endbr(hash) || is_endbr(-hash))) {
bool lsb = hash & 1;
hash >>= 1;
if (lsb)
hash ^= 0x80200003;
}
return hash;
}
static __init int cfi_parse_cmdline(char *str)
{
if (!str)
return -EINVAL;
while (str) {
char *next = strchr(str, ',');
if (next) {
*next = 0;
next++;
}
if (!strcmp(str, "auto")) {
cfi_mode = CFI_DEFAULT;
} else if (!strcmp(str, "off")) {
cfi_mode = CFI_OFF;
cfi_rand = false;
} else if (!strcmp(str, "kcfi")) {
cfi_mode = CFI_KCFI;
} else if (!strcmp(str, "fineibt")) {
cfi_mode = CFI_FINEIBT;
} else if (!strcmp(str, "norand")) {
cfi_rand = false;
} else {
pr_err("Ignoring unknown cfi option (%s).", str);
}
str = next;
}
return 0;
}
early_param("cfi", cfi_parse_cmdline);
/*
* kCFI FineIBT
*
* __cfi_\func: __cfi_\func:
* movl $0x12345678,%eax // 5 endbr64 // 4
* nop subl $0x12345678,%r10d // 7
* nop jz 1f // 2
* nop ud2 // 2
* nop 1: nop // 1
* nop
* nop
* nop
* nop
* nop
* nop
* nop
*
*
* caller: caller:
* movl $(-0x12345678),%r10d // 6 movl $0x12345678,%r10d // 6
* addl $-15(%r11),%r10d // 4 sub $16,%r11 // 4
* je 1f // 2 nop4 // 4
* ud2 // 2
* 1: call __x86_indirect_thunk_r11 // 5 call *%r11; nop2; // 5
*
*/
asm( ".pushsection .rodata \n"
"fineibt_preamble_start: \n"
" endbr64 \n"
" subl $0x12345678, %r10d \n"
" je fineibt_preamble_end \n"
" ud2 \n"
" nop \n"
"fineibt_preamble_end: \n"
".popsection\n"
);
extern u8 fineibt_preamble_start[];
extern u8 fineibt_preamble_end[];
#define fineibt_preamble_size (fineibt_preamble_end - fineibt_preamble_start)
#define fineibt_preamble_hash 7
asm( ".pushsection .rodata \n"
"fineibt_caller_start: \n"
" movl $0x12345678, %r10d \n"
" sub $16, %r11 \n"
ASM_NOP4
"fineibt_caller_end: \n"
".popsection \n"
);
extern u8 fineibt_caller_start[];
extern u8 fineibt_caller_end[];
#define fineibt_caller_size (fineibt_caller_end - fineibt_caller_start)
#define fineibt_caller_hash 2
#define fineibt_caller_jmp (fineibt_caller_size - 2)
static u32 decode_preamble_hash(void *addr)
{
u8 *p = addr;
/* b8 78 56 34 12 mov $0x12345678,%eax */
if (p[0] == 0xb8)
return *(u32 *)(addr + 1);
return 0; /* invalid hash value */
}
static u32 decode_caller_hash(void *addr)
{
u8 *p = addr;
/* 41 ba 78 56 34 12 mov $0x12345678,%r10d */
if (p[0] == 0x41 && p[1] == 0xba)
return -*(u32 *)(addr + 2);
/* e8 0c 78 56 34 12 jmp.d8 +12 */
if (p[0] == JMP8_INSN_OPCODE && p[1] == fineibt_caller_jmp)
return -*(u32 *)(addr + 2);
return 0; /* invalid hash value */
}
/* .retpoline_sites */
static int cfi_disable_callers(s32 *start, s32 *end)
{
/*
* Disable kCFI by patching in a JMP.d8, this leaves the hash immediate
* in tact for later usage. Also see decode_caller_hash() and
* cfi_rewrite_callers().
*/
const u8 jmp[] = { JMP8_INSN_OPCODE, fineibt_caller_jmp };
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
u32 hash;
addr -= fineibt_caller_size;
hash = decode_caller_hash(addr);
if (!hash) /* nocfi callers */
continue;
text_poke_early(addr, jmp, 2);
}
return 0;
}
static int cfi_enable_callers(s32 *start, s32 *end)
{
/*
* Re-enable kCFI, undo what cfi_disable_callers() did.
*/
const u8 mov[] = { 0x41, 0xba };
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
u32 hash;
addr -= fineibt_caller_size;
hash = decode_caller_hash(addr);
if (!hash) /* nocfi callers */
continue;
text_poke_early(addr, mov, 2);
}
return 0;
}
/* .cfi_sites */
static int cfi_rand_preamble(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
u32 hash;
hash = decode_preamble_hash(addr);
if (WARN(!hash, "no CFI hash found at: %pS %px %*ph\n",
addr, addr, 5, addr))
return -EINVAL;
hash = cfi_rehash(hash);
text_poke_early(addr + 1, &hash, 4);
}
return 0;
}
static int cfi_rewrite_preamble(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
u32 hash;
hash = decode_preamble_hash(addr);
if (WARN(!hash, "no CFI hash found at: %pS %px %*ph\n",
addr, addr, 5, addr))
return -EINVAL;
text_poke_early(addr, fineibt_preamble_start, fineibt_preamble_size);
WARN_ON(*(u32 *)(addr + fineibt_preamble_hash) != 0x12345678);
text_poke_early(addr + fineibt_preamble_hash, &hash, 4);
}
return 0;
}
static void cfi_rewrite_endbr(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
poison_endbr(addr+16, false);
}
}
/* .retpoline_sites */
static int cfi_rand_callers(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
u32 hash;
addr -= fineibt_caller_size;
hash = decode_caller_hash(addr);
if (hash) {
hash = -cfi_rehash(hash);
text_poke_early(addr + 2, &hash, 4);
}
}
return 0;
}
static int cfi_rewrite_callers(s32 *start, s32 *end)
{
s32 *s;
for (s = start; s < end; s++) {
void *addr = (void *)s + *s;
u32 hash;
addr -= fineibt_caller_size;
hash = decode_caller_hash(addr);
if (hash) {
text_poke_early(addr, fineibt_caller_start, fineibt_caller_size);
WARN_ON(*(u32 *)(addr + fineibt_caller_hash) != 0x12345678);
text_poke_early(addr + fineibt_caller_hash, &hash, 4);
}
/* rely on apply_retpolines() */
}
return 0;
}
static void __apply_fineibt(s32 *start_retpoline, s32 *end_retpoline,
s32 *start_cfi, s32 *end_cfi, bool builtin)
{
int ret;
if (WARN_ONCE(fineibt_preamble_size != 16,
"FineIBT preamble wrong size: %ld", fineibt_preamble_size))
return;
if (cfi_mode == CFI_DEFAULT) {
cfi_mode = CFI_KCFI;
if (HAS_KERNEL_IBT && cpu_feature_enabled(X86_FEATURE_IBT))
cfi_mode = CFI_FINEIBT;
}
/*
* Rewrite the callers to not use the __cfi_ stubs, such that we might
* rewrite them. This disables all CFI. If this succeeds but any of the
* later stages fails, we're without CFI.
*/
ret = cfi_disable_callers(start_retpoline, end_retpoline);
if (ret)
goto err;
if (cfi_rand) {
if (builtin) {
cfi_seed = get_random_u32();
cfi_bpf_hash = cfi_rehash(cfi_bpf_hash);
cfi_bpf_subprog_hash = cfi_rehash(cfi_bpf_subprog_hash);
}
ret = cfi_rand_preamble(start_cfi, end_cfi);
if (ret)
goto err;
ret = cfi_rand_callers(start_retpoline, end_retpoline);
if (ret)
goto err;
}
switch (cfi_mode) {
case CFI_OFF:
if (builtin)
pr_info("Disabling CFI\n");
return;
case CFI_KCFI:
ret = cfi_enable_callers(start_retpoline, end_retpoline);
if (ret)
goto err;
if (builtin)
pr_info("Using kCFI\n");
return;
case CFI_FINEIBT:
/* place the FineIBT preamble at func()-16 */
ret = cfi_rewrite_preamble(start_cfi, end_cfi);
if (ret)
goto err;
/* rewrite the callers to target func()-16 */
ret = cfi_rewrite_callers(start_retpoline, end_retpoline);
if (ret)
goto err;
/* now that nobody targets func()+0, remove ENDBR there */
cfi_rewrite_endbr(start_cfi, end_cfi);
if (builtin)
pr_info("Using FineIBT CFI\n");
return;
default:
break;
}
err:
pr_err("Something went horribly wrong trying to rewrite the CFI implementation.\n");
}
static inline void poison_hash(void *addr)
{
*(u32 *)addr = 0;
}
static void poison_cfi(void *addr)
{
switch (cfi_mode) {
case CFI_FINEIBT:
/*
* __cfi_\func:
* osp nopl (%rax)
* subl $0, %r10d
* jz 1f
* ud2
* 1: nop
*/
poison_endbr(addr, false);
poison_hash(addr + fineibt_preamble_hash);
break;
case CFI_KCFI:
/*
* __cfi_\func:
* movl $0, %eax
* .skip 11, 0x90
*/
poison_hash(addr + 1);
break;
default:
break;
}
}
#else
static void __apply_fineibt(s32 *start_retpoline, s32 *end_retpoline,
s32 *start_cfi, s32 *end_cfi, bool builtin)
{
}
#ifdef CONFIG_X86_KERNEL_IBT
static void poison_cfi(void *addr) { }
#endif
#endif
void apply_fineibt(s32 *start_retpoline, s32 *end_retpoline,
s32 *start_cfi, s32 *end_cfi)
{
return __apply_fineibt(start_retpoline, end_retpoline,
start_cfi, end_cfi,
/* .builtin = */ false);
}
#ifdef CONFIG_SMP
static void alternatives_smp_lock(const s32 *start, const s32 *end,
u8 *text, u8 *text_end)
{
const s32 *poff;
for (poff = start; poff < end; poff++) {
u8 *ptr = (u8 *)poff + *poff;
if (!*poff || ptr < text || ptr >= text_end)
continue;
/* turn DS segment override prefix into lock prefix */
if (*ptr == 0x3e)
text_poke(ptr, ((unsigned char []){0xf0}), 1);
}
}
static void alternatives_smp_unlock(const s32 *start, const s32 *end,
u8 *text, u8 *text_end)
{
const s32 *poff;
for (poff = start; poff < end; poff++) {
u8 *ptr = (u8 *)poff + *poff;
if (!*poff || ptr < text || ptr >= text_end)
continue;
/* turn lock prefix into DS segment override prefix */
if (*ptr == 0xf0)
text_poke(ptr, ((unsigned char []){0x3E}), 1);
}
}
struct smp_alt_module {
/* what is this ??? */
struct module *mod;
char *name;
/* ptrs to lock prefixes */
const s32 *locks;
const s32 *locks_end;
/* .text segment, needed to avoid patching init code ;) */
u8 *text;
u8 *text_end;
struct list_head next;
};
static LIST_HEAD(smp_alt_modules);
static bool uniproc_patched = false; /* protected by text_mutex */
void __init_or_module alternatives_smp_module_add(struct module *mod,
char *name,
void *locks, void *locks_end,
void *text, void *text_end)
{
struct smp_alt_module *smp;
mutex_lock(&text_mutex);
if (!uniproc_patched)
goto unlock;
if (num_possible_cpus() == 1)
/* Don't bother remembering, we'll never have to undo it. */
goto smp_unlock;
smp = kzalloc(sizeof(*smp), GFP_KERNEL);
if (NULL == smp)
/* we'll run the (safe but slow) SMP code then ... */
goto unlock;
smp->mod = mod;
smp->name = name;
smp->locks = locks;
smp->locks_end = locks_end;
smp->text = text;
smp->text_end = text_end;
DPRINTK(SMP, "locks %p -> %p, text %p -> %p, name %s\n",
smp->locks, smp->locks_end,
smp->text, smp->text_end, smp->name);
list_add_tail(&smp->next, &smp_alt_modules);
smp_unlock:
alternatives_smp_unlock(locks, locks_end, text, text_end);
unlock:
mutex_unlock(&text_mutex);
}
void __init_or_module alternatives_smp_module_del(struct module *mod)
{
struct smp_alt_module *item;
mutex_lock(&text_mutex);
list_for_each_entry(item, &smp_alt_modules, next) {
if (mod != item->mod)
continue;
list_del(&item->next);
kfree(item);
break;
}
mutex_unlock(&text_mutex);
}
void alternatives_enable_smp(void)
{
struct smp_alt_module *mod;
/* Why bother if there are no other CPUs? */
BUG_ON(num_possible_cpus() == 1);
mutex_lock(&text_mutex);
if (uniproc_patched) {
pr_info("switching to SMP code\n");
BUG_ON(num_online_cpus() != 1);
clear_cpu_cap(&boot_cpu_data, X86_FEATURE_UP);
clear_cpu_cap(&cpu_data(0), X86_FEATURE_UP);
list_for_each_entry(mod, &smp_alt_modules, next)
alternatives_smp_lock(mod->locks, mod->locks_end,
mod->text, mod->text_end);
uniproc_patched = false;
}
mutex_unlock(&text_mutex);
}
/*
* Return 1 if the address range is reserved for SMP-alternatives.
* Must hold text_mutex.
*/
int alternatives_text_reserved(void *start, void *end)
{
struct smp_alt_module *mod;
const s32 *poff;
u8 *text_start = start;
u8 *text_end = end;
lockdep_assert_held(&text_mutex);
list_for_each_entry(mod, &smp_alt_modules, next) {
if (mod->text > text_end || mod->text_end < text_start)
continue;
for (poff = mod->locks; poff < mod->locks_end; poff++) {
const u8 *ptr = (const u8 *)poff + *poff;
if (text_start <= ptr && text_end > ptr)
return 1;
}
}
return 0;
}
#endif /* CONFIG_SMP */
/*
* Self-test for the INT3 based CALL emulation code.
*
* This exercises int3_emulate_call() to make sure INT3 pt_regs are set up
* properly and that there is a stack gap between the INT3 frame and the
* previous context. Without this gap doing a virtual PUSH on the interrupted
* stack would corrupt the INT3 IRET frame.
*
* See entry_{32,64}.S for more details.
*/
/*
* We define the int3_magic() function in assembly to control the calling
* convention such that we can 'call' it from assembly.
*/
extern void int3_magic(unsigned int *ptr); /* defined in asm */
asm (
" .pushsection .init.text, \"ax\", @progbits\n"
" .type int3_magic, @function\n"
"int3_magic:\n"
ANNOTATE_NOENDBR
" movl $1, (%" _ASM_ARG1 ")\n"
ASM_RET
" .size int3_magic, .-int3_magic\n"
" .popsection\n"
);
extern void int3_selftest_ip(void); /* defined in asm below */
static int __init
int3_exception_notify(struct notifier_block *self, unsigned long val, void *data)
{
unsigned long selftest = (unsigned long)&int3_selftest_ip;
struct die_args *args = data;
struct pt_regs *regs = args->regs;
OPTIMIZER_HIDE_VAR(selftest);
if (!regs || user_mode(regs))
return NOTIFY_DONE;
if (val != DIE_INT3)
return NOTIFY_DONE;
if (regs->ip - INT3_INSN_SIZE != selftest)
return NOTIFY_DONE;
int3_emulate_call(regs, (unsigned long)&int3_magic);
return NOTIFY_STOP;
}
/* Must be noinline to ensure uniqueness of int3_selftest_ip. */
static noinline void __init int3_selftest(void)
{
static __initdata struct notifier_block int3_exception_nb = {
.notifier_call = int3_exception_notify,
.priority = INT_MAX-1, /* last */
};
unsigned int val = 0;
BUG_ON(register_die_notifier(&int3_exception_nb));
/*
* Basically: int3_magic(&val); but really complicated :-)
*
* INT3 padded with NOP to CALL_INSN_SIZE. The int3_exception_nb
* notifier above will emulate CALL for us.
*/
asm volatile ("int3_selftest_ip:\n\t"
ANNOTATE_NOENDBR
" int3; nop; nop; nop; nop\n\t"
: ASM_CALL_CONSTRAINT
: __ASM_SEL_RAW(a, D) (&val)
: "memory");
BUG_ON(val != 1);
unregister_die_notifier(&int3_exception_nb);
}
static __initdata int __alt_reloc_selftest_addr;
extern void __init __alt_reloc_selftest(void *arg);
__visible noinline void __init __alt_reloc_selftest(void *arg)
{
WARN_ON(arg != &__alt_reloc_selftest_addr);
}
static noinline void __init alt_reloc_selftest(void)
{
/*
* Tests apply_relocation().
*
* This has a relative immediate (CALL) in a place other than the first
* instruction and additionally on x86_64 we get a RIP-relative LEA:
*
* lea 0x0(%rip),%rdi # 5d0: R_X86_64_PC32 .init.data+0x5566c
* call +0 # 5d5: R_X86_64_PLT32 __alt_reloc_selftest-0x4
*
* Getting this wrong will either crash and burn or tickle the WARN
* above.
*/
asm_inline volatile (
ALTERNATIVE("", "lea %[mem], %%" _ASM_ARG1 "; call __alt_reloc_selftest;", X86_FEATURE_ALWAYS)
: /* output */
: [mem] "m" (__alt_reloc_selftest_addr)
: _ASM_ARG1
);
}
void __init alternative_instructions(void)
{
int3_selftest();
/*
* The patching is not fully atomic, so try to avoid local
* interruptions that might execute the to be patched code.
* Other CPUs are not running.
*/
stop_nmi();
/*
* Don't stop machine check exceptions while patching.
* MCEs only happen when something got corrupted and in this
* case we must do something about the corruption.
* Ignoring it is worse than an unlikely patching race.
* Also machine checks tend to be broadcast and if one CPU
* goes into machine check the others follow quickly, so we don't
* expect a machine check to cause undue problems during to code
* patching.
*/
/*
* Make sure to set (artificial) features depending on used paravirt
* functions which can later influence alternative patching.
*/
paravirt_set_cap();
__apply_fineibt(__retpoline_sites, __retpoline_sites_end,
__cfi_sites, __cfi_sites_end, true);
/*
* Rewrite the retpolines, must be done before alternatives since
* those can rewrite the retpoline thunks.
*/
apply_retpolines(__retpoline_sites, __retpoline_sites_end);
apply_returns(__return_sites, __return_sites_end);
apply_alternatives(__alt_instructions, __alt_instructions_end);
/*
* Now all calls are established. Apply the call thunks if
* required.
*/
callthunks_patch_builtin_calls();
/*
* Seal all functions that do not have their address taken.
*/
apply_seal_endbr(__ibt_endbr_seal, __ibt_endbr_seal_end);
#ifdef CONFIG_SMP
/* Patch to UP if other cpus not imminent. */
if (!noreplace_smp && (num_present_cpus() == 1 || setup_max_cpus <= 1)) {
uniproc_patched = true;
alternatives_smp_module_add(NULL, "core kernel",
__smp_locks, __smp_locks_end,
_text, _etext);
}
if (!uniproc_patched || num_possible_cpus() == 1) {
free_init_pages("SMP alternatives",
(unsigned long)__smp_locks,
(unsigned long)__smp_locks_end);
}
#endif
restart_nmi();
alternatives_patched = 1;
alt_reloc_selftest();
}
/**
* text_poke_early - Update instructions on a live kernel at boot time
* @addr: address to modify
* @opcode: source of the copy
* @len: length to copy
*
* When you use this code to patch more than one byte of an instruction
* you need to make sure that other CPUs cannot execute this code in parallel.
* Also no thread must be currently preempted in the middle of these
* instructions. And on the local CPU you need to be protected against NMI or
* MCE handlers seeing an inconsistent instruction while you patch.
*/
void __init_or_module text_poke_early(void *addr, const void *opcode,
size_t len)
{
unsigned long flags;
if (boot_cpu_has(X86_FEATURE_NX) &&
is_module_text_address((unsigned long)addr)) {
/*
* Modules text is marked initially as non-executable, so the
* code cannot be running and speculative code-fetches are
* prevented. Just change the code.
*/
memcpy(addr, opcode, len);
} else {
local_irq_save(flags);
memcpy(addr, opcode, len);
sync_core();
local_irq_restore(flags);
/*
* Could also do a CLFLUSH here to speed up CPU recovery; but
* that causes hangs on some VIA CPUs.
*/
}
}
typedef struct {
struct mm_struct *mm;
} temp_mm_state_t;
/*
* Using a temporary mm allows to set temporary mappings that are not accessible
* by other CPUs. Such mappings are needed to perform sensitive memory writes
* that override the kernel memory protections (e.g., W^X), without exposing the
* temporary page-table mappings that are required for these write operations to
* other CPUs. Using a temporary mm also allows to avoid TLB shootdowns when the
* mapping is torn down.
*
* Context: The temporary mm needs to be used exclusively by a single core. To
* harden security IRQs must be disabled while the temporary mm is
* loaded, thereby preventing interrupt handler bugs from overriding
* the kernel memory protection.
*/
static inline temp_mm_state_t use_temporary_mm(struct mm_struct *mm)
{
temp_mm_state_t temp_state;
lockdep_assert_irqs_disabled();
/*
* Make sure not to be in TLB lazy mode, as otherwise we'll end up
* with a stale address space WITHOUT being in lazy mode after
* restoring the previous mm.
*/
if (this_cpu_read(cpu_tlbstate_shared.is_lazy))
leave_mm();
temp_state.mm = this_cpu_read(cpu_tlbstate.loaded_mm);
switch_mm_irqs_off(NULL, mm, current);
/*
* If breakpoints are enabled, disable them while the temporary mm is
* used. Userspace might set up watchpoints on addresses that are used
* in the temporary mm, which would lead to wrong signals being sent or
* crashes.
*
* Note that breakpoints are not disabled selectively, which also causes
* kernel breakpoints (e.g., perf's) to be disabled. This might be
* undesirable, but still seems reasonable as the code that runs in the
* temporary mm should be short.
*/
if (hw_breakpoint_active())
hw_breakpoint_disable();
return temp_state;
}
static inline void unuse_temporary_mm(temp_mm_state_t prev_state)
{
lockdep_assert_irqs_disabled();
switch_mm_irqs_off(NULL, prev_state.mm, current);
/*
* Restore the breakpoints if they were disabled before the temporary mm
* was loaded.
*/
if (hw_breakpoint_active())
hw_breakpoint_restore();
}
__ro_after_init struct mm_struct *poking_mm;
__ro_after_init unsigned long poking_addr;
static void text_poke_memcpy(void *dst, const void *src, size_t len)
{
memcpy(dst, src, len);
}
static void text_poke_memset(void *dst, const void *src, size_t len)
{
int c = *(const int *)src;
memset(dst, c, len);
}
typedef void text_poke_f(void *dst, const void *src, size_t len);
static void *__text_poke(text_poke_f func, void *addr, const void *src, size_t len)
{
bool cross_page_boundary = offset_in_page(addr) + len > PAGE_SIZE;
struct page *pages[2] = {NULL};
temp_mm_state_t prev;
unsigned long flags;
pte_t pte, *ptep;
spinlock_t *ptl;
pgprot_t pgprot;
/*
* While boot memory allocator is running we cannot use struct pages as
* they are not yet initialized. There is no way to recover.
*/
BUG_ON(!after_bootmem);
if (!core_kernel_text((unsigned long)addr)) {
pages[0] = vmalloc_to_page(addr);
if (cross_page_boundary)
pages[1] = vmalloc_to_page(addr + PAGE_SIZE);
} else {
pages[0] = virt_to_page(addr);
WARN_ON(!PageReserved(pages[0]));
if (cross_page_boundary)
pages[1] = virt_to_page(addr + PAGE_SIZE);
}
/*
* If something went wrong, crash and burn since recovery paths are not
* implemented.
*/
BUG_ON(!pages[0] || (cross_page_boundary && !pages[1]));
/*
* Map the page without the global bit, as TLB flushing is done with
* flush_tlb_mm_range(), which is intended for non-global PTEs.
*/
pgprot = __pgprot(pgprot_val(PAGE_KERNEL) & ~_PAGE_GLOBAL);
/*
* The lock is not really needed, but this allows to avoid open-coding.
*/
ptep = get_locked_pte(poking_mm, poking_addr, &ptl);
/*
* This must not fail; preallocated in poking_init().
*/
VM_BUG_ON(!ptep);
local_irq_save(flags);
pte = mk_pte(pages[0], pgprot);
set_pte_at(poking_mm, poking_addr, ptep, pte);
if (cross_page_boundary) {
pte = mk_pte(pages[1], pgprot);
set_pte_at(poking_mm, poking_addr + PAGE_SIZE, ptep + 1, pte);
}
/*
* Loading the temporary mm behaves as a compiler barrier, which
* guarantees that the PTE will be set at the time memcpy() is done.
*/
prev = use_temporary_mm(poking_mm);
kasan_disable_current();
func((u8 *)poking_addr + offset_in_page(addr), src, len);
kasan_enable_current();
/*
* Ensure that the PTE is only cleared after the instructions of memcpy
* were issued by using a compiler barrier.
*/
barrier();
pte_clear(poking_mm, poking_addr, ptep);
if (cross_page_boundary)
pte_clear(poking_mm, poking_addr + PAGE_SIZE, ptep + 1);
/*
* Loading the previous page-table hierarchy requires a serializing
* instruction that already allows the core to see the updated version.
* Xen-PV is assumed to serialize execution in a similar manner.
*/
unuse_temporary_mm(prev);
/*
* Flushing the TLB might involve IPIs, which would require enabled
* IRQs, but not if the mm is not used, as it is in this point.
*/
flush_tlb_mm_range(poking_mm, poking_addr, poking_addr +
(cross_page_boundary ? 2 : 1) * PAGE_SIZE,
PAGE_SHIFT, false);
if (func == text_poke_memcpy) {
/*
* If the text does not match what we just wrote then something is
* fundamentally screwy; there's nothing we can really do about that.
*/
BUG_ON(memcmp(addr, src, len));
}
local_irq_restore(flags);
pte_unmap_unlock(ptep, ptl);
return addr;
}
/**
* text_poke - Update instructions on a live kernel
* @addr: address to modify
* @opcode: source of the copy
* @len: length to copy
*
* Only atomic text poke/set should be allowed when not doing early patching.
* It means the size must be writable atomically and the address must be aligned
* in a way that permits an atomic write. It also makes sure we fit on a single
* page.
*
* Note that the caller must ensure that if the modified code is part of a
* module, the module would not be removed during poking. This can be achieved
* by registering a module notifier, and ordering module removal and patching
* through a mutex.
*/
void *text_poke(void *addr, const void *opcode, size_t len)
{
lockdep_assert_held(&text_mutex);
return __text_poke(text_poke_memcpy, addr, opcode, len);
}
/**
* text_poke_kgdb - Update instructions on a live kernel by kgdb
* @addr: address to modify
* @opcode: source of the copy
* @len: length to copy
*
* Only atomic text poke/set should be allowed when not doing early patching.
* It means the size must be writable atomically and the address must be aligned
* in a way that permits an atomic write. It also makes sure we fit on a single
* page.
*
* Context: should only be used by kgdb, which ensures no other core is running,
* despite the fact it does not hold the text_mutex.
*/
void *text_poke_kgdb(void *addr, const void *opcode, size_t len)
{
return __text_poke(text_poke_memcpy, addr, opcode, len);
}
void *text_poke_copy_locked(void *addr, const void *opcode, size_t len,
bool core_ok)
{
unsigned long start = (unsigned long)addr;
size_t patched = 0;
if (WARN_ON_ONCE(!core_ok && core_kernel_text(start)))
return NULL;
while (patched < len) {
unsigned long ptr = start + patched;
size_t s;
s = min_t(size_t, PAGE_SIZE * 2 - offset_in_page(ptr), len - patched);
__text_poke(text_poke_memcpy, (void *)ptr, opcode + patched, s);
patched += s;
}
return addr;
}
/**
* text_poke_copy - Copy instructions into (an unused part of) RX memory
* @addr: address to modify
* @opcode: source of the copy
* @len: length to copy, could be more than 2x PAGE_SIZE
*
* Not safe against concurrent execution; useful for JITs to dump
* new code blocks into unused regions of RX memory. Can be used in
* conjunction with synchronize_rcu_tasks() to wait for existing
* execution to quiesce after having made sure no existing functions
* pointers are live.
*/
void *text_poke_copy(void *addr, const void *opcode, size_t len)
{
mutex_lock(&text_mutex);
addr = text_poke_copy_locked(addr, opcode, len, false);
mutex_unlock(&text_mutex);
return addr;
}
/**
* text_poke_set - memset into (an unused part of) RX memory
* @addr: address to modify
* @c: the byte to fill the area with
* @len: length to copy, could be more than 2x PAGE_SIZE
*
* This is useful to overwrite unused regions of RX memory with illegal
* instructions.
*/
void *text_poke_set(void *addr, int c, size_t len)
{
unsigned long start = (unsigned long)addr;
size_t patched = 0;
if (WARN_ON_ONCE(core_kernel_text(start)))
return NULL;
mutex_lock(&text_mutex);
while (patched < len) {
unsigned long ptr = start + patched;
size_t s;
s = min_t(size_t, PAGE_SIZE * 2 - offset_in_page(ptr), len - patched);
__text_poke(text_poke_memset, (void *)ptr, (void *)&c, s);
patched += s;
}
mutex_unlock(&text_mutex);
return addr;
}
static void do_sync_core(void *info)
{
sync_core();
}
void text_poke_sync(void)
{
on_each_cpu(do_sync_core, NULL, 1);
}
/*
* NOTE: crazy scheme to allow patching Jcc.d32 but not increase the size of
* this thing. When len == 6 everything is prefixed with 0x0f and we map
* opcode to Jcc.d8, using len to distinguish.
*/
struct text_poke_loc {
/* addr := _stext + rel_addr */
s32 rel_addr;
s32 disp;
u8 len;
u8 opcode;
const u8 text[POKE_MAX_OPCODE_SIZE];
/* see text_poke_bp_batch() */
u8 old;
};
struct bp_patching_desc {
struct text_poke_loc *vec;
int nr_entries;
atomic_t refs;
};
static struct bp_patching_desc bp_desc;
static __always_inline
struct bp_patching_desc *try_get_desc(void)
{
struct bp_patching_desc *desc = &bp_desc;
if (!raw_atomic_inc_not_zero(&desc->refs))
return NULL;
return desc;
}
static __always_inline void put_desc(void)
{
struct bp_patching_desc *desc = &bp_desc;
smp_mb__before_atomic();
raw_atomic_dec(&desc->refs);
}
static __always_inline void *text_poke_addr(struct text_poke_loc *tp)
{
return _stext + tp->rel_addr;
}
static __always_inline int patch_cmp(const void *key, const void *elt)
{
struct text_poke_loc *tp = (struct text_poke_loc *) elt;
if (key < text_poke_addr(tp))
return -1;
if (key > text_poke_addr(tp))
return 1;
return 0;
}
noinstr int poke_int3_handler(struct pt_regs *regs)
{
struct bp_patching_desc *desc;
struct text_poke_loc *tp;
int ret = 0;
void *ip;
if (user_mode(regs))
return 0;
/*
* Having observed our INT3 instruction, we now must observe
* bp_desc with non-zero refcount:
*
* bp_desc.refs = 1 INT3
* WMB RMB
* write INT3 if (bp_desc.refs != 0)
*/
smp_rmb();
desc = try_get_desc();
if (!desc)
return 0;
/*
* Discount the INT3. See text_poke_bp_batch().
*/
ip = (void *) regs->ip - INT3_INSN_SIZE;
/*
* Skip the binary search if there is a single member in the vector.
*/
if (unlikely(desc->nr_entries > 1)) {
tp = __inline_bsearch(ip, desc->vec, desc->nr_entries,
sizeof(struct text_poke_loc),
patch_cmp);
if (!tp)
goto out_put;
} else {
tp = desc->vec;
if (text_poke_addr(tp) != ip)
goto out_put;
}
ip += tp->len;
switch (tp->opcode) {
case INT3_INSN_OPCODE:
/*
* Someone poked an explicit INT3, they'll want to handle it,
* do not consume.
*/
goto out_put;
case RET_INSN_OPCODE:
int3_emulate_ret(regs);
break;
case CALL_INSN_OPCODE:
int3_emulate_call(regs, (long)ip + tp->disp);
break;
case JMP32_INSN_OPCODE:
case JMP8_INSN_OPCODE:
int3_emulate_jmp(regs, (long)ip + tp->disp);
break;
case 0x70 ... 0x7f: /* Jcc */
int3_emulate_jcc(regs, tp->opcode & 0xf, (long)ip, tp->disp);
break;
default:
BUG();
}
ret = 1;
out_put:
put_desc();
return ret;
}
#define TP_VEC_MAX (PAGE_SIZE / sizeof(struct text_poke_loc))
static struct text_poke_loc tp_vec[TP_VEC_MAX];
static int tp_vec_nr;
/**
* text_poke_bp_batch() -- update instructions on live kernel on SMP
* @tp: vector of instructions to patch
* @nr_entries: number of entries in the vector
*
* Modify multi-byte instruction by using int3 breakpoint on SMP.
* We completely avoid stop_machine() here, and achieve the
* synchronization using int3 breakpoint.
*
* The way it is done:
* - For each entry in the vector:
* - add a int3 trap to the address that will be patched
* - sync cores
* - For each entry in the vector:
* - update all but the first byte of the patched range
* - sync cores
* - For each entry in the vector:
* - replace the first byte (int3) by the first byte of
* replacing opcode
* - sync cores
*/
static void text_poke_bp_batch(struct text_poke_loc *tp, unsigned int nr_entries)
{
unsigned char int3 = INT3_INSN_OPCODE;
unsigned int i;
int do_sync;
lockdep_assert_held(&text_mutex);
bp_desc.vec = tp;
bp_desc.nr_entries = nr_entries;
/*
* Corresponds to the implicit memory barrier in try_get_desc() to
* ensure reading a non-zero refcount provides up to date bp_desc data.
*/
atomic_set_release(&bp_desc.refs, 1);
/*
* Function tracing can enable thousands of places that need to be
* updated. This can take quite some time, and with full kernel debugging
* enabled, this could cause the softlockup watchdog to trigger.
* This function gets called every 256 entries added to be patched.
* Call cond_resched() here to make sure that other tasks can get scheduled
* while processing all the functions being patched.
*/
cond_resched();
/*
* Corresponding read barrier in int3 notifier for making sure the
* nr_entries and handler are correctly ordered wrt. patching.
*/
smp_wmb();
/*
* First step: add a int3 trap to the address that will be patched.
*/
for (i = 0; i < nr_entries; i++) {
tp[i].old = *(u8 *)text_poke_addr(&tp[i]);
text_poke(text_poke_addr(&tp[i]), &int3, INT3_INSN_SIZE);
}
text_poke_sync();
/*
* Second step: update all but the first byte of the patched range.
*/
for (do_sync = 0, i = 0; i < nr_entries; i++) {
u8 old[POKE_MAX_OPCODE_SIZE+1] = { tp[i].old, };
u8 _new[POKE_MAX_OPCODE_SIZE+1];
const u8 *new = tp[i].text;
int len = tp[i].len;
if (len - INT3_INSN_SIZE > 0) {
memcpy(old + INT3_INSN_SIZE,
text_poke_addr(&tp[i]) + INT3_INSN_SIZE,
len - INT3_INSN_SIZE);
if (len == 6) {
_new[0] = 0x0f;
memcpy(_new + 1, new, 5);
new = _new;
}
text_poke(text_poke_addr(&tp[i]) + INT3_INSN_SIZE,
new + INT3_INSN_SIZE,
len - INT3_INSN_SIZE);
do_sync++;
}
/*
* Emit a perf event to record the text poke, primarily to
* support Intel PT decoding which must walk the executable code
* to reconstruct the trace. The flow up to here is:
* - write INT3 byte
* - IPI-SYNC
* - write instruction tail
* At this point the actual control flow will be through the
* INT3 and handler and not hit the old or new instruction.
* Intel PT outputs FUP/TIP packets for the INT3, so the flow
* can still be decoded. Subsequently:
* - emit RECORD_TEXT_POKE with the new instruction
* - IPI-SYNC
* - write first byte
* - IPI-SYNC
* So before the text poke event timestamp, the decoder will see
* either the old instruction flow or FUP/TIP of INT3. After the
* text poke event timestamp, the decoder will see either the
* new instruction flow or FUP/TIP of INT3. Thus decoders can
* use the timestamp as the point at which to modify the
* executable code.
* The old instruction is recorded so that the event can be
* processed forwards or backwards.
*/
perf_event_text_poke(text_poke_addr(&tp[i]), old, len, new, len);
}
if (do_sync) {
/*
* According to Intel, this core syncing is very likely
* not necessary and we'd be safe even without it. But
* better safe than sorry (plus there's not only Intel).
*/
text_poke_sync();
}
/*
* Third step: replace the first byte (int3) by the first byte of
* replacing opcode.
*/
for (do_sync = 0, i = 0; i < nr_entries; i++) {
u8 byte = tp[i].text[0];
if (tp[i].len == 6)
byte = 0x0f;
if (byte == INT3_INSN_OPCODE)
continue;
text_poke(text_poke_addr(&tp[i]), &byte, INT3_INSN_SIZE);
do_sync++;
}
if (do_sync)
text_poke_sync();
/*
* Remove and wait for refs to be zero.
*/
if (!atomic_dec_and_test(&bp_desc.refs))
atomic_cond_read_acquire(&bp_desc.refs, !VAL);
}
static void text_poke_loc_init(struct text_poke_loc *tp, void *addr,
const void *opcode, size_t len, const void *emulate)
{
struct insn insn;
int ret, i = 0;
if (len == 6)
i = 1;
memcpy((void *)tp->text, opcode+i, len-i);
if (!emulate)
emulate = opcode;
ret = insn_decode_kernel(&insn, emulate);
BUG_ON(ret < 0);
tp->rel_addr = addr - (void *)_stext;
tp->len = len;
tp->opcode = insn.opcode.bytes[0];
if (is_jcc32(&insn)) {
/*
* Map Jcc.d32 onto Jcc.d8 and use len to distinguish.
*/
tp->opcode = insn.opcode.bytes[1] - 0x10;
}
switch (tp->opcode) {
case RET_INSN_OPCODE:
case JMP32_INSN_OPCODE:
case JMP8_INSN_OPCODE:
/*
* Control flow instructions without implied execution of the
* next instruction can be padded with INT3.
*/
for (i = insn.length; i < len; i++)
BUG_ON(tp->text[i] != INT3_INSN_OPCODE);
break;
default:
BUG_ON(len != insn.length);
}
switch (tp->opcode) {
case INT3_INSN_OPCODE:
case RET_INSN_OPCODE:
break;
case CALL_INSN_OPCODE:
case JMP32_INSN_OPCODE:
case JMP8_INSN_OPCODE:
case 0x70 ... 0x7f: /* Jcc */
tp->disp = insn.immediate.value;
break;
default: /* assume NOP */
switch (len) {
case 2: /* NOP2 -- emulate as JMP8+0 */
BUG_ON(memcmp(emulate, x86_nops[len], len));
tp->opcode = JMP8_INSN_OPCODE;
tp->disp = 0;
break;
case 5: /* NOP5 -- emulate as JMP32+0 */
BUG_ON(memcmp(emulate, x86_nops[len], len));
tp->opcode = JMP32_INSN_OPCODE;
tp->disp = 0;
break;
default: /* unknown instruction */
BUG();
}
break;
}
}
/*
* We hard rely on the tp_vec being ordered; ensure this is so by flushing
* early if needed.
*/
static bool tp_order_fail(void *addr)
{
struct text_poke_loc *tp;
if (!tp_vec_nr)
return false;
if (!addr) /* force */
return true;
tp = &tp_vec[tp_vec_nr - 1];
if ((unsigned long)text_poke_addr(tp) > (unsigned long)addr)
return true;
return false;
}
static void text_poke_flush(void *addr)
{
if (tp_vec_nr == TP_VEC_MAX || tp_order_fail(addr)) {
text_poke_bp_batch(tp_vec, tp_vec_nr);
tp_vec_nr = 0;
}
}
void text_poke_finish(void)
{
text_poke_flush(NULL);
}
void __ref text_poke_queue(void *addr, const void *opcode, size_t len, const void *emulate)
{
struct text_poke_loc *tp;
text_poke_flush(addr);
tp = &tp_vec[tp_vec_nr++];
text_poke_loc_init(tp, addr, opcode, len, emulate);
}
/**
* text_poke_bp() -- update instructions on live kernel on SMP
* @addr: address to patch
* @opcode: opcode of new instruction
* @len: length to copy
* @emulate: instruction to be emulated
*
* Update a single instruction with the vector in the stack, avoiding
* dynamically allocated memory. This function should be used when it is
* not possible to allocate memory.
*/
void __ref text_poke_bp(void *addr, const void *opcode, size_t len, const void *emulate)
{
struct text_poke_loc tp;
text_poke_loc_init(&tp, addr, opcode, len, emulate);
text_poke_bp_batch(&tp, 1);
}