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linux-next/arch/arm64/kernel/module.c
Torsten Duwe 3b23e4991f arm64: implement ftrace with regs
This patch implements FTRACE_WITH_REGS for arm64, which allows a traced
function's arguments (and some other registers) to be captured into a
struct pt_regs, allowing these to be inspected and/or modified. This is
a building block for live-patching, where a function's arguments may be
forwarded to another function. This is also necessary to enable ftrace
and in-kernel pointer authentication at the same time, as it allows the
LR value to be captured and adjusted prior to signing.

Using GCC's -fpatchable-function-entry=N option, we can have the
compiler insert a configurable number of NOPs between the function entry
point and the usual prologue. This also ensures functions are AAPCS
compliant (e.g. disabling inter-procedural register allocation).

For example, with -fpatchable-function-entry=2, GCC 8.1.0 compiles the
following:

| unsigned long bar(void);
|
| unsigned long foo(void)
| {
|         return bar() + 1;
| }

... to:

| <foo>:
|         nop
|         nop
|         stp     x29, x30, [sp, #-16]!
|         mov     x29, sp
|         bl      0 <bar>
|         add     x0, x0, #0x1
|         ldp     x29, x30, [sp], #16
|         ret

This patch builds the kernel with -fpatchable-function-entry=2,
prefixing each function with two NOPs. To trace a function, we replace
these NOPs with a sequence that saves the LR into a GPR, then calls an
ftrace entry assembly function which saves this and other relevant
registers:

| mov	x9, x30
| bl	<ftrace-entry>

Since patchable functions are AAPCS compliant (and the kernel does not
use x18 as a platform register), x9-x18 can be safely clobbered in the
patched sequence and the ftrace entry code.

There are now two ftrace entry functions, ftrace_regs_entry (which saves
all GPRs), and ftrace_entry (which saves the bare minimum). A PLT is
allocated for each within modules.

Signed-off-by: Torsten Duwe <duwe@suse.de>
[Mark: rework asm, comments, PLTs, initialization, commit message]
Signed-off-by: Mark Rutland <mark.rutland@arm.com>
Reviewed-by: Amit Daniel Kachhap <amit.kachhap@arm.com>
Reviewed-by: Ard Biesheuvel <ard.biesheuvel@linaro.org>
Reviewed-by: Torsten Duwe <duwe@suse.de>
Tested-by: Amit Daniel Kachhap <amit.kachhap@arm.com>
Tested-by: Torsten Duwe <duwe@suse.de>
Cc: AKASHI Takahiro <takahiro.akashi@linaro.org>
Cc: Catalin Marinas <catalin.marinas@arm.com>
Cc: Josh Poimboeuf <jpoimboe@redhat.com>
Cc: Julien Thierry <jthierry@redhat.com>
Cc: Will Deacon <will@kernel.org>
2019-11-06 14:17:35 +00:00

529 lines
14 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* AArch64 loadable module support.
*
* Copyright (C) 2012 ARM Limited
*
* Author: Will Deacon <will.deacon@arm.com>
*/
#include <linux/bitops.h>
#include <linux/elf.h>
#include <linux/ftrace.h>
#include <linux/gfp.h>
#include <linux/kasan.h>
#include <linux/kernel.h>
#include <linux/mm.h>
#include <linux/moduleloader.h>
#include <linux/vmalloc.h>
#include <asm/alternative.h>
#include <asm/insn.h>
#include <asm/sections.h>
void *module_alloc(unsigned long size)
{
u64 module_alloc_end = module_alloc_base + MODULES_VSIZE;
gfp_t gfp_mask = GFP_KERNEL;
void *p;
/* Silence the initial allocation */
if (IS_ENABLED(CONFIG_ARM64_MODULE_PLTS))
gfp_mask |= __GFP_NOWARN;
if (IS_ENABLED(CONFIG_KASAN))
/* don't exceed the static module region - see below */
module_alloc_end = MODULES_END;
p = __vmalloc_node_range(size, MODULE_ALIGN, module_alloc_base,
module_alloc_end, gfp_mask, PAGE_KERNEL, 0,
NUMA_NO_NODE, __builtin_return_address(0));
if (!p && IS_ENABLED(CONFIG_ARM64_MODULE_PLTS) &&
!IS_ENABLED(CONFIG_KASAN))
/*
* KASAN can only deal with module allocations being served
* from the reserved module region, since the remainder of
* the vmalloc region is already backed by zero shadow pages,
* and punching holes into it is non-trivial. Since the module
* region is not randomized when KASAN is enabled, it is even
* less likely that the module region gets exhausted, so we
* can simply omit this fallback in that case.
*/
p = __vmalloc_node_range(size, MODULE_ALIGN, module_alloc_base,
module_alloc_base + SZ_2G, GFP_KERNEL,
PAGE_KERNEL, 0, NUMA_NO_NODE,
__builtin_return_address(0));
if (p && (kasan_module_alloc(p, size) < 0)) {
vfree(p);
return NULL;
}
return p;
}
enum aarch64_reloc_op {
RELOC_OP_NONE,
RELOC_OP_ABS,
RELOC_OP_PREL,
RELOC_OP_PAGE,
};
static u64 do_reloc(enum aarch64_reloc_op reloc_op, __le32 *place, u64 val)
{
switch (reloc_op) {
case RELOC_OP_ABS:
return val;
case RELOC_OP_PREL:
return val - (u64)place;
case RELOC_OP_PAGE:
return (val & ~0xfff) - ((u64)place & ~0xfff);
case RELOC_OP_NONE:
return 0;
}
pr_err("do_reloc: unknown relocation operation %d\n", reloc_op);
return 0;
}
static int reloc_data(enum aarch64_reloc_op op, void *place, u64 val, int len)
{
s64 sval = do_reloc(op, place, val);
/*
* The ELF psABI for AArch64 documents the 16-bit and 32-bit place
* relative and absolute relocations as having a range of [-2^15, 2^16)
* or [-2^31, 2^32), respectively. However, in order to be able to
* detect overflows reliably, we have to choose whether we interpret
* such quantities as signed or as unsigned, and stick with it.
* The way we organize our address space requires a signed
* interpretation of 32-bit relative references, so let's use that
* for all R_AARCH64_PRELxx relocations. This means our upper
* bound for overflow detection should be Sxx_MAX rather than Uxx_MAX.
*/
switch (len) {
case 16:
*(s16 *)place = sval;
switch (op) {
case RELOC_OP_ABS:
if (sval < 0 || sval > U16_MAX)
return -ERANGE;
break;
case RELOC_OP_PREL:
if (sval < S16_MIN || sval > S16_MAX)
return -ERANGE;
break;
default:
pr_err("Invalid 16-bit data relocation (%d)\n", op);
return 0;
}
break;
case 32:
*(s32 *)place = sval;
switch (op) {
case RELOC_OP_ABS:
if (sval < 0 || sval > U32_MAX)
return -ERANGE;
break;
case RELOC_OP_PREL:
if (sval < S32_MIN || sval > S32_MAX)
return -ERANGE;
break;
default:
pr_err("Invalid 32-bit data relocation (%d)\n", op);
return 0;
}
break;
case 64:
*(s64 *)place = sval;
break;
default:
pr_err("Invalid length (%d) for data relocation\n", len);
return 0;
}
return 0;
}
enum aarch64_insn_movw_imm_type {
AARCH64_INSN_IMM_MOVNZ,
AARCH64_INSN_IMM_MOVKZ,
};
static int reloc_insn_movw(enum aarch64_reloc_op op, __le32 *place, u64 val,
int lsb, enum aarch64_insn_movw_imm_type imm_type)
{
u64 imm;
s64 sval;
u32 insn = le32_to_cpu(*place);
sval = do_reloc(op, place, val);
imm = sval >> lsb;
if (imm_type == AARCH64_INSN_IMM_MOVNZ) {
/*
* For signed MOVW relocations, we have to manipulate the
* instruction encoding depending on whether or not the
* immediate is less than zero.
*/
insn &= ~(3 << 29);
if (sval >= 0) {
/* >=0: Set the instruction to MOVZ (opcode 10b). */
insn |= 2 << 29;
} else {
/*
* <0: Set the instruction to MOVN (opcode 00b).
* Since we've masked the opcode already, we
* don't need to do anything other than
* inverting the new immediate field.
*/
imm = ~imm;
}
}
/* Update the instruction with the new encoding. */
insn = aarch64_insn_encode_immediate(AARCH64_INSN_IMM_16, insn, imm);
*place = cpu_to_le32(insn);
if (imm > U16_MAX)
return -ERANGE;
return 0;
}
static int reloc_insn_imm(enum aarch64_reloc_op op, __le32 *place, u64 val,
int lsb, int len, enum aarch64_insn_imm_type imm_type)
{
u64 imm, imm_mask;
s64 sval;
u32 insn = le32_to_cpu(*place);
/* Calculate the relocation value. */
sval = do_reloc(op, place, val);
sval >>= lsb;
/* Extract the value bits and shift them to bit 0. */
imm_mask = (BIT(lsb + len) - 1) >> lsb;
imm = sval & imm_mask;
/* Update the instruction's immediate field. */
insn = aarch64_insn_encode_immediate(imm_type, insn, imm);
*place = cpu_to_le32(insn);
/*
* Extract the upper value bits (including the sign bit) and
* shift them to bit 0.
*/
sval = (s64)(sval & ~(imm_mask >> 1)) >> (len - 1);
/*
* Overflow has occurred if the upper bits are not all equal to
* the sign bit of the value.
*/
if ((u64)(sval + 1) >= 2)
return -ERANGE;
return 0;
}
static int reloc_insn_adrp(struct module *mod, Elf64_Shdr *sechdrs,
__le32 *place, u64 val)
{
u32 insn;
if (!is_forbidden_offset_for_adrp(place))
return reloc_insn_imm(RELOC_OP_PAGE, place, val, 12, 21,
AARCH64_INSN_IMM_ADR);
/* patch ADRP to ADR if it is in range */
if (!reloc_insn_imm(RELOC_OP_PREL, place, val & ~0xfff, 0, 21,
AARCH64_INSN_IMM_ADR)) {
insn = le32_to_cpu(*place);
insn &= ~BIT(31);
} else {
/* out of range for ADR -> emit a veneer */
val = module_emit_veneer_for_adrp(mod, sechdrs, place, val & ~0xfff);
if (!val)
return -ENOEXEC;
insn = aarch64_insn_gen_branch_imm((u64)place, val,
AARCH64_INSN_BRANCH_NOLINK);
}
*place = cpu_to_le32(insn);
return 0;
}
int apply_relocate_add(Elf64_Shdr *sechdrs,
const char *strtab,
unsigned int symindex,
unsigned int relsec,
struct module *me)
{
unsigned int i;
int ovf;
bool overflow_check;
Elf64_Sym *sym;
void *loc;
u64 val;
Elf64_Rela *rel = (void *)sechdrs[relsec].sh_addr;
for (i = 0; i < sechdrs[relsec].sh_size / sizeof(*rel); i++) {
/* loc corresponds to P in the AArch64 ELF document. */
loc = (void *)sechdrs[sechdrs[relsec].sh_info].sh_addr
+ rel[i].r_offset;
/* sym is the ELF symbol we're referring to. */
sym = (Elf64_Sym *)sechdrs[symindex].sh_addr
+ ELF64_R_SYM(rel[i].r_info);
/* val corresponds to (S + A) in the AArch64 ELF document. */
val = sym->st_value + rel[i].r_addend;
/* Check for overflow by default. */
overflow_check = true;
/* Perform the static relocation. */
switch (ELF64_R_TYPE(rel[i].r_info)) {
/* Null relocations. */
case R_ARM_NONE:
case R_AARCH64_NONE:
ovf = 0;
break;
/* Data relocations. */
case R_AARCH64_ABS64:
overflow_check = false;
ovf = reloc_data(RELOC_OP_ABS, loc, val, 64);
break;
case R_AARCH64_ABS32:
ovf = reloc_data(RELOC_OP_ABS, loc, val, 32);
break;
case R_AARCH64_ABS16:
ovf = reloc_data(RELOC_OP_ABS, loc, val, 16);
break;
case R_AARCH64_PREL64:
overflow_check = false;
ovf = reloc_data(RELOC_OP_PREL, loc, val, 64);
break;
case R_AARCH64_PREL32:
ovf = reloc_data(RELOC_OP_PREL, loc, val, 32);
break;
case R_AARCH64_PREL16:
ovf = reloc_data(RELOC_OP_PREL, loc, val, 16);
break;
/* MOVW instruction relocations. */
case R_AARCH64_MOVW_UABS_G0_NC:
overflow_check = false;
/* Fall through */
case R_AARCH64_MOVW_UABS_G0:
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 0,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_UABS_G1_NC:
overflow_check = false;
/* Fall through */
case R_AARCH64_MOVW_UABS_G1:
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 16,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_UABS_G2_NC:
overflow_check = false;
/* Fall through */
case R_AARCH64_MOVW_UABS_G2:
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 32,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_UABS_G3:
/* We're using the top bits so we can't overflow. */
overflow_check = false;
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 48,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_SABS_G0:
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 0,
AARCH64_INSN_IMM_MOVNZ);
break;
case R_AARCH64_MOVW_SABS_G1:
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 16,
AARCH64_INSN_IMM_MOVNZ);
break;
case R_AARCH64_MOVW_SABS_G2:
ovf = reloc_insn_movw(RELOC_OP_ABS, loc, val, 32,
AARCH64_INSN_IMM_MOVNZ);
break;
case R_AARCH64_MOVW_PREL_G0_NC:
overflow_check = false;
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 0,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_PREL_G0:
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 0,
AARCH64_INSN_IMM_MOVNZ);
break;
case R_AARCH64_MOVW_PREL_G1_NC:
overflow_check = false;
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 16,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_PREL_G1:
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 16,
AARCH64_INSN_IMM_MOVNZ);
break;
case R_AARCH64_MOVW_PREL_G2_NC:
overflow_check = false;
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 32,
AARCH64_INSN_IMM_MOVKZ);
break;
case R_AARCH64_MOVW_PREL_G2:
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 32,
AARCH64_INSN_IMM_MOVNZ);
break;
case R_AARCH64_MOVW_PREL_G3:
/* We're using the top bits so we can't overflow. */
overflow_check = false;
ovf = reloc_insn_movw(RELOC_OP_PREL, loc, val, 48,
AARCH64_INSN_IMM_MOVNZ);
break;
/* Immediate instruction relocations. */
case R_AARCH64_LD_PREL_LO19:
ovf = reloc_insn_imm(RELOC_OP_PREL, loc, val, 2, 19,
AARCH64_INSN_IMM_19);
break;
case R_AARCH64_ADR_PREL_LO21:
ovf = reloc_insn_imm(RELOC_OP_PREL, loc, val, 0, 21,
AARCH64_INSN_IMM_ADR);
break;
case R_AARCH64_ADR_PREL_PG_HI21_NC:
overflow_check = false;
/* Fall through */
case R_AARCH64_ADR_PREL_PG_HI21:
ovf = reloc_insn_adrp(me, sechdrs, loc, val);
if (ovf && ovf != -ERANGE)
return ovf;
break;
case R_AARCH64_ADD_ABS_LO12_NC:
case R_AARCH64_LDST8_ABS_LO12_NC:
overflow_check = false;
ovf = reloc_insn_imm(RELOC_OP_ABS, loc, val, 0, 12,
AARCH64_INSN_IMM_12);
break;
case R_AARCH64_LDST16_ABS_LO12_NC:
overflow_check = false;
ovf = reloc_insn_imm(RELOC_OP_ABS, loc, val, 1, 11,
AARCH64_INSN_IMM_12);
break;
case R_AARCH64_LDST32_ABS_LO12_NC:
overflow_check = false;
ovf = reloc_insn_imm(RELOC_OP_ABS, loc, val, 2, 10,
AARCH64_INSN_IMM_12);
break;
case R_AARCH64_LDST64_ABS_LO12_NC:
overflow_check = false;
ovf = reloc_insn_imm(RELOC_OP_ABS, loc, val, 3, 9,
AARCH64_INSN_IMM_12);
break;
case R_AARCH64_LDST128_ABS_LO12_NC:
overflow_check = false;
ovf = reloc_insn_imm(RELOC_OP_ABS, loc, val, 4, 8,
AARCH64_INSN_IMM_12);
break;
case R_AARCH64_TSTBR14:
ovf = reloc_insn_imm(RELOC_OP_PREL, loc, val, 2, 14,
AARCH64_INSN_IMM_14);
break;
case R_AARCH64_CONDBR19:
ovf = reloc_insn_imm(RELOC_OP_PREL, loc, val, 2, 19,
AARCH64_INSN_IMM_19);
break;
case R_AARCH64_JUMP26:
case R_AARCH64_CALL26:
ovf = reloc_insn_imm(RELOC_OP_PREL, loc, val, 2, 26,
AARCH64_INSN_IMM_26);
if (IS_ENABLED(CONFIG_ARM64_MODULE_PLTS) &&
ovf == -ERANGE) {
val = module_emit_plt_entry(me, sechdrs, loc, &rel[i], sym);
if (!val)
return -ENOEXEC;
ovf = reloc_insn_imm(RELOC_OP_PREL, loc, val, 2,
26, AARCH64_INSN_IMM_26);
}
break;
default:
pr_err("module %s: unsupported RELA relocation: %llu\n",
me->name, ELF64_R_TYPE(rel[i].r_info));
return -ENOEXEC;
}
if (overflow_check && ovf == -ERANGE)
goto overflow;
}
return 0;
overflow:
pr_err("module %s: overflow in relocation type %d val %Lx\n",
me->name, (int)ELF64_R_TYPE(rel[i].r_info), val);
return -ENOEXEC;
}
static const Elf_Shdr *find_section(const Elf_Ehdr *hdr,
const Elf_Shdr *sechdrs,
const char *name)
{
const Elf_Shdr *s, *se;
const char *secstrs = (void *)hdr + sechdrs[hdr->e_shstrndx].sh_offset;
for (s = sechdrs, se = sechdrs + hdr->e_shnum; s < se; s++) {
if (strcmp(name, secstrs + s->sh_name) == 0)
return s;
}
return NULL;
}
static inline void __init_plt(struct plt_entry *plt, unsigned long addr)
{
*plt = get_plt_entry(addr, plt);
}
static int module_init_ftrace_plt(const Elf_Ehdr *hdr,
const Elf_Shdr *sechdrs,
struct module *mod)
{
#if defined(CONFIG_ARM64_MODULE_PLTS) && defined(CONFIG_DYNAMIC_FTRACE)
const Elf_Shdr *s;
struct plt_entry *plts;
s = find_section(hdr, sechdrs, ".text.ftrace_trampoline");
if (!s)
return -ENOEXEC;
plts = (void *)s->sh_addr;
__init_plt(&plts[FTRACE_PLT_IDX], FTRACE_ADDR);
if (IS_ENABLED(CONFIG_DYNAMIC_FTRACE_WITH_REGS))
__init_plt(&plts[FTRACE_REGS_PLT_IDX], FTRACE_REGS_ADDR);
mod->arch.ftrace_trampolines = plts;
#endif
return 0;
}
int module_finalize(const Elf_Ehdr *hdr,
const Elf_Shdr *sechdrs,
struct module *me)
{
const Elf_Shdr *s;
s = find_section(hdr, sechdrs, ".altinstructions");
if (s)
apply_alternatives_module((void *)s->sh_addr, s->sh_size);
return module_init_ftrace_plt(hdr, sechdrs, me);
}