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e5c46fde75
After emulating a misaligned load or store issued in Thumb mode, we have to advance the IT state by hand, or it will get out of sync with the actual instruction stream, which means we'll end up applying the wrong condition code to subsequent instructions. This might corrupt the program state rather catastrophically. So borrow the it_advance() helper from the probing code, and use it on CPSR if the emulated instruction is Thumb. Cc: <stable@vger.kernel.org> Reviewed-by: Linus Walleij <linus.walleij@linaro.org> Signed-off-by: Ard Biesheuvel <ardb@kernel.org> Signed-off-by: Russell King (Oracle) <rmk+kernel@armlinux.org.uk>
386 lines
11 KiB
C
386 lines
11 KiB
C
/* SPDX-License-Identifier: GPL-2.0-only */
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/*
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* arch/arm/probes/decode.h
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*
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* Copyright (C) 2011 Jon Medhurst <tixy@yxit.co.uk>.
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*
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* Some contents moved here from arch/arm/include/asm/kprobes.h which is
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* Copyright (C) 2006, 2007 Motorola Inc.
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*/
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#ifndef _ARM_KERNEL_PROBES_H
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#define _ARM_KERNEL_PROBES_H
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#include <linux/types.h>
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#include <linux/stddef.h>
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#include <asm/probes.h>
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#include <asm/ptrace.h>
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#include <asm/kprobes.h>
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void __init arm_probes_decode_init(void);
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extern probes_check_cc * const probes_condition_checks[16];
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#if __LINUX_ARM_ARCH__ >= 7
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/* str_pc_offset is architecturally defined from ARMv7 onwards */
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#define str_pc_offset 8
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#define find_str_pc_offset()
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#else /* __LINUX_ARM_ARCH__ < 7 */
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/* We need a run-time check to determine str_pc_offset */
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extern int str_pc_offset;
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void __init find_str_pc_offset(void);
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#endif
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static inline void __kprobes bx_write_pc(long pcv, struct pt_regs *regs)
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{
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long cpsr = regs->ARM_cpsr;
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if (pcv & 0x1) {
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cpsr |= PSR_T_BIT;
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pcv &= ~0x1;
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} else {
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cpsr &= ~PSR_T_BIT;
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pcv &= ~0x2; /* Avoid UNPREDICTABLE address allignment */
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}
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regs->ARM_cpsr = cpsr;
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regs->ARM_pc = pcv;
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}
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#if __LINUX_ARM_ARCH__ >= 6
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/* Kernels built for >= ARMv6 should never run on <= ARMv5 hardware, so... */
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#define load_write_pc_interworks true
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#define test_load_write_pc_interworking()
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#else /* __LINUX_ARM_ARCH__ < 6 */
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/* We need run-time testing to determine if load_write_pc() should interwork. */
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extern bool load_write_pc_interworks;
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void __init test_load_write_pc_interworking(void);
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#endif
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static inline void __kprobes load_write_pc(long pcv, struct pt_regs *regs)
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{
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if (load_write_pc_interworks)
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bx_write_pc(pcv, regs);
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else
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regs->ARM_pc = pcv;
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}
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#if __LINUX_ARM_ARCH__ >= 7
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#define alu_write_pc_interworks true
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#define test_alu_write_pc_interworking()
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#elif __LINUX_ARM_ARCH__ <= 5
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/* Kernels built for <= ARMv5 should never run on >= ARMv6 hardware, so... */
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#define alu_write_pc_interworks false
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#define test_alu_write_pc_interworking()
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#else /* __LINUX_ARM_ARCH__ == 6 */
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/* We could be an ARMv6 binary on ARMv7 hardware so we need a run-time check. */
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extern bool alu_write_pc_interworks;
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void __init test_alu_write_pc_interworking(void);
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#endif /* __LINUX_ARM_ARCH__ == 6 */
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static inline void __kprobes alu_write_pc(long pcv, struct pt_regs *regs)
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{
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if (alu_write_pc_interworks)
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bx_write_pc(pcv, regs);
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else
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regs->ARM_pc = pcv;
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}
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/*
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* Test if load/store instructions writeback the address register.
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* if P (bit 24) == 0 or W (bit 21) == 1
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*/
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#define is_writeback(insn) ((insn ^ 0x01000000) & 0x01200000)
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/*
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* The following definitions and macros are used to build instruction
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* decoding tables for use by probes_decode_insn.
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*
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* These tables are a concatenation of entries each of which consist of one of
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* the decode_* structs. All of the fields in every type of decode structure
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* are of the union type decode_item, therefore the entire decode table can be
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* viewed as an array of these and declared like:
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*
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* static const union decode_item table_name[] = {};
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*
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* In order to construct each entry in the table, macros are used to
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* initialise a number of sequential decode_item values in a layout which
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* matches the relevant struct. E.g. DECODE_SIMULATE initialise a struct
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* decode_simulate by initialising four decode_item objects like this...
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*
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* {.bits = _type},
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* {.bits = _mask},
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* {.bits = _value},
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* {.action = _handler},
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*
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* Initialising a specified member of the union means that the compiler
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* will produce a warning if the argument is of an incorrect type.
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*
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* Below is a list of each of the macros used to initialise entries and a
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* description of the action performed when that entry is matched to an
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* instruction. A match is found when (instruction & mask) == value.
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*
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* DECODE_TABLE(mask, value, table)
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* Instruction decoding jumps to parsing the new sub-table 'table'.
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*
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* DECODE_CUSTOM(mask, value, decoder)
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* The value of 'decoder' is used as an index into the array of
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* action functions, and the retrieved decoder function is invoked
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* to complete decoding of the instruction.
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*
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* DECODE_SIMULATE(mask, value, handler)
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* The probes instruction handler is set to the value found by
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* indexing into the action array using the value of 'handler'. This
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* will be used to simulate the instruction when the probe is hit.
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* Decoding returns with INSN_GOOD_NO_SLOT.
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*
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* DECODE_EMULATE(mask, value, handler)
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* The probes instruction handler is set to the value found by
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* indexing into the action array using the value of 'handler'. This
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* will be used to emulate the instruction when the probe is hit. The
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* modified instruction (see below) is placed in the probes instruction
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* slot so it may be called by the emulation code. Decoding returns
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* with INSN_GOOD.
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*
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* DECODE_REJECT(mask, value)
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* Instruction decoding fails with INSN_REJECTED
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*
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* DECODE_OR(mask, value)
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* This allows the mask/value test of multiple table entries to be
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* logically ORed. Once an 'or' entry is matched the decoding action to
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* be performed is that of the next entry which isn't an 'or'. E.g.
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*
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* DECODE_OR (mask1, value1)
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* DECODE_OR (mask2, value2)
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* DECODE_SIMULATE (mask3, value3, simulation_handler)
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*
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* This means that if any of the three mask/value pairs match the
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* instruction being decoded, then 'simulation_handler' will be used
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* for it.
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*
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* Both the SIMULATE and EMULATE macros have a second form which take an
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* additional 'regs' argument.
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*
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* DECODE_SIMULATEX(mask, value, handler, regs)
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* DECODE_EMULATEX (mask, value, handler, regs)
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*
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* These are used to specify what kind of CPU register is encoded in each of the
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* least significant 5 nibbles of the instruction being decoded. The regs value
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* is specified using the REGS macro, this takes any of the REG_TYPE_* values
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* from enum decode_reg_type as arguments; only the '*' part of the name is
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* given. E.g.
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*
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* REGS(0, ANY, NOPC, 0, ANY)
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*
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* This indicates an instruction is encoded like:
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*
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* bits 19..16 ignore
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* bits 15..12 any register allowed here
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* bits 11.. 8 any register except PC allowed here
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* bits 7.. 4 ignore
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* bits 3.. 0 any register allowed here
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*
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* This register specification is checked after a decode table entry is found to
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* match an instruction (through the mask/value test). Any invalid register then
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* found in the instruction will cause decoding to fail with INSN_REJECTED. In
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* the above example this would happen if bits 11..8 of the instruction were
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* 1111, indicating R15 or PC.
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*
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* As well as checking for legal combinations of registers, this data is also
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* used to modify the registers encoded in the instructions so that an
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* emulation routines can use it. (See decode_regs() and INSN_NEW_BITS.)
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*
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* Here is a real example which matches ARM instructions of the form
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* "AND <Rd>,<Rn>,<Rm>,<shift> <Rs>"
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*
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* DECODE_EMULATEX (0x0e000090, 0x00000010, PROBES_DATA_PROCESSING_REG,
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* REGS(ANY, ANY, NOPC, 0, ANY)),
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* ^ ^ ^ ^
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* Rn Rd Rs Rm
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*
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* Decoding the instruction "AND R4, R5, R6, ASL R15" will be rejected because
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* Rs == R15
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*
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* Decoding the instruction "AND R4, R5, R6, ASL R7" will be accepted and the
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* instruction will be modified to "AND R0, R2, R3, ASL R1" and then placed into
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* the kprobes instruction slot. This can then be called later by the handler
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* function emulate_rd12rn16rm0rs8_rwflags (a pointer to which is retrieved from
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* the indicated slot in the action array), in order to simulate the instruction.
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*/
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enum decode_type {
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DECODE_TYPE_END,
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DECODE_TYPE_TABLE,
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DECODE_TYPE_CUSTOM,
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DECODE_TYPE_SIMULATE,
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DECODE_TYPE_EMULATE,
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DECODE_TYPE_OR,
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DECODE_TYPE_REJECT,
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NUM_DECODE_TYPES /* Must be last enum */
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};
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#define DECODE_TYPE_BITS 4
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#define DECODE_TYPE_MASK ((1 << DECODE_TYPE_BITS) - 1)
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enum decode_reg_type {
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REG_TYPE_NONE = 0, /* Not a register, ignore */
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REG_TYPE_ANY, /* Any register allowed */
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REG_TYPE_SAMEAS16, /* Register should be same as that at bits 19..16 */
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REG_TYPE_SP, /* Register must be SP */
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REG_TYPE_PC, /* Register must be PC */
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REG_TYPE_NOSP, /* Register must not be SP */
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REG_TYPE_NOSPPC, /* Register must not be SP or PC */
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REG_TYPE_NOPC, /* Register must not be PC */
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REG_TYPE_NOPCWB, /* No PC if load/store write-back flag also set */
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/* The following types are used when the encoding for PC indicates
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* another instruction form. This distiction only matters for test
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* case coverage checks.
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*/
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REG_TYPE_NOPCX, /* Register must not be PC */
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REG_TYPE_NOSPPCX, /* Register must not be SP or PC */
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/* Alias to allow '0' arg to be used in REGS macro. */
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REG_TYPE_0 = REG_TYPE_NONE
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};
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#define REGS(r16, r12, r8, r4, r0) \
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(((REG_TYPE_##r16) << 16) + \
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((REG_TYPE_##r12) << 12) + \
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((REG_TYPE_##r8) << 8) + \
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((REG_TYPE_##r4) << 4) + \
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(REG_TYPE_##r0))
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union decode_item {
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u32 bits;
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const union decode_item *table;
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int action;
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};
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struct decode_header;
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typedef enum probes_insn (probes_custom_decode_t)(probes_opcode_t,
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struct arch_probes_insn *,
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const struct decode_header *);
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union decode_action {
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probes_insn_handler_t *handler;
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probes_custom_decode_t *decoder;
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};
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typedef enum probes_insn (probes_check_t)(probes_opcode_t,
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struct arch_probes_insn *,
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const struct decode_header *);
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struct decode_checker {
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probes_check_t *checker;
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};
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#define DECODE_END \
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{.bits = DECODE_TYPE_END}
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struct decode_header {
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union decode_item type_regs;
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union decode_item mask;
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union decode_item value;
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};
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#define DECODE_HEADER(_type, _mask, _value, _regs) \
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{.bits = (_type) | ((_regs) << DECODE_TYPE_BITS)}, \
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{.bits = (_mask)}, \
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{.bits = (_value)}
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struct decode_table {
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struct decode_header header;
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union decode_item table;
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};
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#define DECODE_TABLE(_mask, _value, _table) \
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DECODE_HEADER(DECODE_TYPE_TABLE, _mask, _value, 0), \
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{.table = (_table)}
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struct decode_custom {
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struct decode_header header;
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union decode_item decoder;
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};
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#define DECODE_CUSTOM(_mask, _value, _decoder) \
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DECODE_HEADER(DECODE_TYPE_CUSTOM, _mask, _value, 0), \
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{.action = (_decoder)}
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struct decode_simulate {
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struct decode_header header;
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union decode_item handler;
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};
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#define DECODE_SIMULATEX(_mask, _value, _handler, _regs) \
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DECODE_HEADER(DECODE_TYPE_SIMULATE, _mask, _value, _regs), \
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{.action = (_handler)}
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#define DECODE_SIMULATE(_mask, _value, _handler) \
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DECODE_SIMULATEX(_mask, _value, _handler, 0)
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struct decode_emulate {
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struct decode_header header;
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union decode_item handler;
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};
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#define DECODE_EMULATEX(_mask, _value, _handler, _regs) \
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DECODE_HEADER(DECODE_TYPE_EMULATE, _mask, _value, _regs), \
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{.action = (_handler)}
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#define DECODE_EMULATE(_mask, _value, _handler) \
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DECODE_EMULATEX(_mask, _value, _handler, 0)
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struct decode_or {
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struct decode_header header;
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};
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#define DECODE_OR(_mask, _value) \
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DECODE_HEADER(DECODE_TYPE_OR, _mask, _value, 0)
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enum probes_insn {
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INSN_REJECTED,
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INSN_GOOD,
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INSN_GOOD_NO_SLOT
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};
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struct decode_reject {
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struct decode_header header;
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};
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#define DECODE_REJECT(_mask, _value) \
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DECODE_HEADER(DECODE_TYPE_REJECT, _mask, _value, 0)
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probes_insn_handler_t probes_simulate_nop;
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probes_insn_handler_t probes_emulate_none;
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int __kprobes
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probes_decode_insn(probes_opcode_t insn, struct arch_probes_insn *asi,
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const union decode_item *table, bool thumb, bool emulate,
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const union decode_action *actions,
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const struct decode_checker **checkers);
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#endif
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