Bochs/bochs/instrument/instrumentation.txt
2015-02-19 20:23:08 +00:00

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README-instrumentation
To use instrumentation features in bochs, you must compile in support for it.
You should build a custom instrumentation library in a separate directory in
the "instrument/" directory. To tell configure which instrumentation library
you want to use, use the "--enable-instrumentation" option. The default
library consists of a set of stubs, and the following are equivalent:
./configure [...] --enable-instrumentation
./configure [...] --enable-instrumentation="instrument/stubs"
You could make a separate directory with your custom library, for example
"instrument/myinstrument", copy the contents of the "instrument/stubs"
directory to it, then customize it. Use:
./configure [...] --enable-instrumentation="instrument/myinstrument"
-----------------------------------------------------------------------------
BOCHS instrumentation callbacks
void bx_instr_init_env();
The callback is called when Bochs is initialized, before of reading .bochsrc.
It can be used for registration of parameters in siminterface. Then
when bx_instr_init() is called it can access configuration parameters defined
by bx_instr_init_env(), so instrumentalization module can use additional
options in .bochsrc.
void bx_instr_exit_env();
The callback is called each time Bochs exits.
void bx_instr_initialize(unsigned cpu);
The callback is called each time, when Bochs initializes the CPU object. It
can be used for initialization of user's data, dynamic memory allocation and
etc.
void bx_instr_exit(unsigned cpu);
The callback is called each time, when Bochs destructs the CPU object. It can
be used for destruction of user's data, allocated by bx_instr_init callback.
void bx_instr_reset(unsigned cpu, unsigned type);
The callback is called each time, when Bochs resets the CPU object. It would
be executed once at the start of simulation and each time that user presses
RESET BUTTON on the simulator's control panel.
void bx_instr_hlt(unsigned cpu);
The callback is called each time, when Bochs' emulated CPU enters HALT or
SHUTDOWN state.
void bx_instr_mwait(unsigned cpu, bx_phy_address addr, unsigned len, Bit32u flags);
The callback is called each time, when Bochs' emulated CPU enters to the MWAIT
state. The callback receives monitored memory range and MWAIT flags as a
parameters.
void bx_instr_cnear_branch_taken(unsigned cpu, bx_address branch_rip, bx_address new_rip);
The callback is called each time, when currently executed instruction is a
conditional near branch and it is taken.
void bx_instr_cnear_branch_not_taken(unsigned cpu, bx_address branch_rip);
The callback is called each time, when currently executed instruction is a
conditional near branch and it is not taken.
void bx_instr_ucnear_branch(unsigned cpu, unsigned what, bx_address branch_rip, bx_address new_rip);
The callback is called each time, when currently executed instruction is an
unconditional near branch (always taken).
void bx_instr_far_branch(unsigned cpu, unsigned what, Bit16u prev_cs, bx_address prev_rip, Bit16u new_cs, bx_address new_rip);
The callback is called each time, when currently executed instruction is an
unconditional far branch (always taken).
Possible operation types, passed through bx_instr_ucnear_branch and bx_instr_far_branch are:
#define BX_INSTR_IS_JMP 10
#define BX_INSTR_IS_JMP_INDIRECT 11
#define BX_INSTR_IS_CALL 12
#define BX_INSTR_IS_CALL_INDIRECT 13
#define BX_INSTR_IS_RET 14
#define BX_INSTR_IS_IRET 15
#define BX_INSTR_IS_INT 16
#define BX_INSTR_IS_SYSCALL 17
#define BX_INSTR_IS_SYSRET 18
#define BX_INSTR_IS_SYSENTER 19
#define BX_INSTR_IS_SYSEXIT 20
void bx_instr_vmexit(unsigned cpu, Bit32u reason, Bit64u qualification);
This callback is called right before Bochs executes a VMEXIT.
void bx_instr_opcode(unsigned cpu, bxInstruction_c *i, const Bit8u *opcode, unsigned len, bx_bool is32, bx_bool is64);
The callback is called each time, when Bochs completes to decode a new
instruction. Through this callback function Bochs could provide an opcode of
the instruction, opcode length and an execution mode (16/32/64).
Note, that Bochs uses translation caches so each simulated instruction might
be executed multiple times but decoded only once.
void bx_instr_interrupt(unsigned cpu, unsigned vector);
The callback is called each time, when Bochs simulator executes an interrupt
(software interrupt, hardware interrupt or an exception).
void bx_instr_exception(unsigned cpu, unsigned vector, unsigned error_code);
The callback is called each time, when Bochs simulator executes an exception.
void bx_instr_hwinterrupt(unsigned cpu, unsigned vector, Bit16u cs, bx_address rip);
The callback is called each time, when Bochs simulator executes a hardware
interrupt.
void bx_instr_clflush(unsigned cpu, bx_address laddr, bx_phy_address paddr);
The callback is called each time the CLFLUSH instruction is executed.
void bx_instr_tlb_cntrl(unsigned cpu, unsigned what, bx_phy_address new_cr_value);
void bx_instr_cache_cntrl(unsigned cpu, unsigned what);
The callback is called each time, when Bochs simulator executes a cache/tlb
control instruction.
Possible instruction types, passed through bx_instr_tlb_cntrl are:
#define BX_INSTR_MOV_CR0 10
#define BX_INSTR_MOV_CR3 11
#define BX_INSTR_MOV_CR4 12
#define BX_INSTR_TASK_SWITCH 13
#define BX_INSTR_CONTEXT_SWITCH 14 /* VMM and SMM enter/exit */
#define BX_INSTR_INVLPG 15
#define BX_INSTR_INVEPT 16
#define BX_INSTR_INVVPID 17
#define BX_INSTR_INVPCID 18
The new_cr_value is provided for first 4 instruction types only and undefined
for all others.
Possible instruction types, passed through bx_instr_cache_cntrl are:
#define BX_INSTR_INVD 10
#define BX_INSTR_WBINVD 11
void bx_instr_prefetch_hint(unsigned cpu, unsigned what, unsigned seg, bx_address offset);
The callback is called each time, when Bochs simulator executes a PREFETCH
instruction.
Possible PREFETCH types:
#define BX_INSTR_PREFETCH_NTA 00
#define BX_INSTR_PREFETCH_T0 01
#define BX_INSTR_PREFETCH_T1 02
#define BX_INSTR_PREFETCH_T2 03
The seg/offset arguments indicate the address of the requested prefetch.
void bx_instr_wrmsr(unsigned cpu, unsigned msr, Bit64u value);
This callback is called each time when WRMSR instruction is executed.
MSR number and written value passed as parameters to the callback function.
void bx_instr_repeat_iteration(unsigned cpu, bxInstruction_c *i);
The callback is called each time, when Bochs simulator starts a new repeat
iteration.
void bx_instr_before_execution(unsigned cpu, bxInstruction_c *i);
The callback is called each time, when Bochs simulator starts a new
instruction execution. In case of repeat instruction the callback will
be called only once before the first iteration will be started.
void bx_instr_after_execution(unsigned cpu, bxInstruction_c *i);
The callback is called each time, when Bochs simulator finishes any
instruction execution. In case of repeat instruction the callback will
be called only once after all repeat iterations.
void bx_instr_lin_access(unsigned cpu, bx_address lin, bx_address phy, unsigned len, unsigned memtype, unsigned rw);
The callback is called each time, when Bochs simulator executes a linear
memory access. Note that no page split accesses will be generated because
Bochs splits page split accesses to two different memory accesses during its
execution flow. The callback also will not be generated in case of direct
physical memory access like page walks, SMM, VMM or SVM operations.
Possible access types are: BX_READ, BX_WRITE and BX_RW.
Currently the callback is not supported when repeat-speedups optimization is
enabled.
void bx_instr_phy_access(unsigned cpu, bx_address lin, bx_address phy, unsigned len, unsigned memtype, unsigned rw);
The callback is called each time, when Bochs simulator executes a physical
memory access. Physical accesses include memory accesses generated by the
CPU during page walks, SMM, VMM or SVM operations. Note that no page split
accesses will be generated because Bochs splits page split accesses to two
different memory accesses during its execution flow.
Possible access types are: BX_READ, BX_WRITE and BX_RW.
void bx_instr_inp(Bit16u addr, unsigned len);
void bx_instr_inp2(Bit16u addr, unsigned len, unsigned val);
void bx_instr_outp(Bit16u addr, unsigned len, unsigned val);
These callback functions are a feedback from various system devices.
-----------------------------------------------------------------------------
Known problems:
1. BX_INSTR_LIN_ACCESS doesn't work when repeat-speedups feature is enabled.
Feature requests:
1. BX_INSTR_CNEAR_BRANCH_NOT_TAKEN callback should have an additional
'not taken' new_rip parameter.
2. BX_INSTR_SMI, BX_INSTR_NMI, BX_INSTR_SIPI and other external events
callbacks