static void add_read_operands(xed_dot_graph_supp_t* gg,
xed_decoded_inst_t* xedd,
xed_dot_node_t* n)
{
xed_uint_t i, noperands;
xed_reg_enum_t r;
const xed_inst_t* xi = 0;
xed_bool_t found = 0;
xi = xed_decoded_inst_inst(xedd);
noperands = xed_inst_noperands(xi);
for( i=0; i < noperands ; i++) {
int memop = -1;
const xed_operand_t* op = xed_inst_operand(xi,i);
xed_operand_enum_t opname = xed_operand_name(op);
if (xed_operand_is_register(opname) ||
xed_operand_is_memory_addressing_register(opname)) {
if (xed_operand_read(op)) {
/* add edge to n */
r = xed_decoded_inst_get_reg(xedd, opname);
found |= add_edge(gg, n, r, XED_DOT_EDGE_SOLID);
}
continue;
}
if (opname == XED_OPERAND_MEM0)
memop = 0;
else if (opname == XED_OPERAND_MEM1 )
memop = 1;
if (memop != -1) {
/* get reads of base/index regs, if any */
xed_reg_enum_t base, indx;
base = xed_decoded_inst_get_base_reg(xedd,memop);
indx = xed_decoded_inst_get_index_reg(xedd,memop);
if (base != XED_REG_INVALID)
found |= add_edge(gg, n, base, XED_DOT_EDGE_SOLID);
indx = xed_decoded_inst_get_index_reg(xedd,memop);
if (indx != XED_REG_INVALID)
found |= add_edge(gg, n, indx, XED_DOT_EDGE_SOLID);
}
} /* for */
if (!found) {
/* add an edge from start */
xed_dot_edge(gg->g, gg->start, n, XED_DOT_EDGE_SOLID);
}
}
void print_operands(xed_decoded_inst_t* xedd) {
unsigned int i = 0;
xed_inst_t const* const xi = xed_decoded_inst_inst(xedd);
const unsigned int noperands = xed_inst_noperands(xi);
for( i=0; i < noperands ; i++) {
xed_operand_t const* op = xed_inst_operand(xi,i);
xed_operand_enum_t op_name = xed_operand_name(op);
if (xed_operand_is_register(op_name)) {
xed_reg_enum_t reg = xed_decoded_inst_get_reg(xedd,op_name);
xed_operand_action_enum_t rw = xed_operand_rw(op);
printf("%2d: %5s %5s\n",
i,
xed_reg_enum_t2str(reg),
xed_operand_action_enum_t2str(rw));
}
}
}
unwind_interval *
process_and(xed_decoded_inst_t *xptr, const xed_inst_t *xi, interval_arg_t *iarg,
mem_alloc m_alloc)
{
unwind_interval *next = iarg->current;
const xed_operand_t* op0 = xed_inst_operand(xi,0);
xed_operand_enum_t op0_name = xed_operand_name(op0);
if (op0_name == XED_OPERAND_REG0) {
xed_reg_enum_t reg0 = xed_decoded_inst_get_reg(xptr, op0_name);
if (x86_isReg_SP(reg0) && UWI_RECIPE(iarg->current)->bp_status != BP_UNCHANGED) {
//-----------------------------------------------------------------------
// we are adjusting the stack pointer via 'and' instruction
//-----------------------------------------------------------------------
next = new_ui(iarg->ins + xed_decoded_inst_get_length(xptr),
RA_BP_FRAME, UWI_RECIPE(iarg->current)->sp_ra_pos, UWI_RECIPE(iarg->current)->bp_ra_pos,
UWI_RECIPE(iarg->current)->bp_status, UWI_RECIPE(iarg->current)->sp_bp_pos,
UWI_RECIPE(iarg->current)->bp_bp_pos, iarg->current, m_alloc);
}
}
return next;
}
static PyObject *get_reg(instruction_t *self, PyObject *args)
{
int i;
xed_decoded_inst_t *decoded_inst;
xed_reg_enum_t reg;
PyObject *r = NULL;
if(PyArg_ParseTuple(args, "i", &i) == 0)
goto _err;
decoded_inst = self->decoded_inst;
if(i <= XED_OPERAND_INVALID || i >= XED_OPERAND_LAST)
{
PyErr_SetString(PyExc_ValueError, "Invalid register");
goto _err;
}
reg = xed_decoded_inst_get_reg(decoded_inst, i);
r = PyInt_FromLong(reg);
_err:
return r;
}
unwind_interval *
process_addsub(xed_decoded_inst_t *xptr, const xed_inst_t *xi, interval_arg_t *iarg)
{
highwatermark_t *hw_tmp = &(iarg->highwatermark);
unwind_interval *next = iarg->current;
const xed_operand_t* op0 = xed_inst_operand(xi,0);
const xed_operand_t* op1 = xed_inst_operand(xi,1);
xed_operand_enum_t op0_name = xed_operand_name(op0);
if (op0_name == XED_OPERAND_REG0) {
xed_reg_enum_t reg0 = xed_decoded_inst_get_reg(xptr, op0_name);
if (x86_isReg_SP(reg0)) {
//-----------------------------------------------------------------------
// we are adjusting the stack pointer
//-----------------------------------------------------------------------
if (xed_operand_name(op1) == XED_OPERAND_IMM0) {
int sign = (iclass_eq(xptr, XED_ICLASS_ADD)) ? -1 : 1;
long immedv = sign * xed_decoded_inst_get_signed_immediate(xptr);
ra_loc istatus = iarg->current->ra_status;
if ((istatus == RA_STD_FRAME) && (immedv > 0) &&
(hw_tmp->state & HW_SP_DECREMENTED)) {
//-------------------------------------------------------------------
// if we are in a standard frame and we see a second subtract,
// it is time to convert interval to a BP frame to minimize
// the chance we get the wrong offset for the return address
// in a routine that manipulates SP frequently (as in
// leapfrog_mod_leapfrog_ in the SPEC CPU2006 benchmark
// 459.GemsFDTD, when compiled with PGI 7.0.3 with high levels
// of optimization).
//
// 9 December 2007 -- John Mellor-Crummey
//-------------------------------------------------------------------
}
next = new_ui(iarg->ins + xed_decoded_inst_get_length(xptr),
istatus, iarg->current->sp_ra_pos + immedv, iarg->current->bp_ra_pos,
iarg->current->bp_status, iarg->current->sp_bp_pos + immedv,
iarg->current->bp_bp_pos, iarg->current);
if (immedv > 0) {
if (HW_TEST_STATE(hw_tmp->state, 0, HW_SP_DECREMENTED)) {
//-----------------------------------------------------------------
// set the highwatermark and canonical interval upon seeing
// the FIRST subtract from SP; take no action on subsequent
// subtracts.
//
// test case: main in SPEC CPU2006 benchmark 470.lbm
// contains multiple subtracts from SP when compiled with
// PGI 7.0.3 with high levels of optimization. the first
// subtract from SP is to set up the frame; subsequent ones
// are to reserve space for arguments passed to functions.
//
// 9 December 2007 -- John Mellor-Crummey
//-----------------------------------------------------------------
hw_tmp->uwi = next;
hw_tmp->succ_inst_ptr =
iarg->ins + xed_decoded_inst_get_length(xptr);
hw_tmp->state =
HW_NEW_STATE(hw_tmp->state, HW_SP_DECREMENTED);
iarg->canonical_interval = next;
}
}
} else {
if (iarg->current->ra_status != RA_BP_FRAME){
//-------------------------------------------------------------------
// no immediate in add/subtract from stack pointer; switch to
// BP_FRAME
//
// 9 December 2007 -- John Mellor-Crummey
//-------------------------------------------------------------------
next = new_ui(iarg->ins + xed_decoded_inst_get_length(xptr), RA_BP_FRAME,
iarg->current->sp_ra_pos, iarg->current->bp_ra_pos,
iarg->current->bp_status, iarg->current->sp_bp_pos,
iarg->current->bp_bp_pos, iarg->current);
iarg->bp_frames_found = true;
}
}
}
}
return next;
}
/* This is the central function
Given a memory address, reads a bunch of memory bytes and
calls the disassembler to obtain the information
Then it stores the information into the eh EntryHeader
*/
void decode_address(uint32_t address, EntryHeader *eh, int ignore_taint)
{
unsigned char insn_buf[MAX_INSN_BYTES];
unsigned int is_stackpush = 0, is_stackpop = 0;
unsigned int stackpushpop_acc = 0;
if (xed2chris_regmapping[XED_REG_EAX][0] == 0) {
init_xed2chris();
assert(xed2chris_regmapping[XED_REG_EAX][0] != 0);
}
/* Read memory from TEMU */
TEMU_read_mem(address, MAX_INSN_BYTES, insn_buf);
/* Disassemble instruction buffer */
xed_decoded_inst_zero_set_mode(&xedd, &dstate);
xed_error_enum_t xed_error =
xed_decode(&xedd, STATIC_CAST(const xed_uint8_t*,insn_buf), MAX_INSN_BYTES);
xed_bool_t okay = (xed_error == XED_ERROR_NONE);
if (!okay) return;
// Increase counters
tstats.insn_counter_decoded++;
int i;
/* Clear out Entry header */
memset(eh, 0, sizeof(EntryHeader));
/* Copy the address and instruction size */
eh->address = address;
eh->inst_size = xed_decoded_inst_get_length(&xedd);
if (eh->inst_size > MAX_INSN_BYTES) eh->inst_size = MAX_INSN_BYTES;
/* Copy instruction rawbytes */
memcpy(eh->rawbytes, insn_buf, eh->inst_size);
/* Get the number of XED operands */
const xed_inst_t* xi = xed_decoded_inst_inst(&xedd);
int xed_ops = xed_inst_noperands(xi);
int op_idx = -1;
/* Get the category of the instruction */
xed_category_enum_t category = xed_decoded_inst_get_category(&xedd);
/* Iterate over the XED operands */
for(i = 0; i < xed_ops; i++) {
if(op_idx >= MAX_NUM_OPERANDS)
break;
//assert(op_idx < MAX_NUM_OPERANDS);
/* Get operand */
const xed_operand_t* op = xed_inst_operand(xi,i);
xed_operand_enum_t op_name = xed_operand_name(op);
switch(op_name) {
/* Register */
case XED_OPERAND_REG0:
case XED_OPERAND_REG1:
case XED_OPERAND_REG2:
case XED_OPERAND_REG3:
case XED_OPERAND_REG4:
case XED_OPERAND_REG5:
case XED_OPERAND_REG6:
case XED_OPERAND_REG7:
case XED_OPERAND_REG8:
case XED_OPERAND_REG9:
case XED_OPERAND_REG10:
case XED_OPERAND_REG11:
case XED_OPERAND_REG12:
case XED_OPERAND_REG13:
case XED_OPERAND_REG14:
case XED_OPERAND_REG15: {
xed_reg_enum_t reg_id = xed_decoded_inst_get_reg(&xedd, op_name);
int regnum = xed2chris_regmapping[reg_id][1];
// Special handling for Push
if (reg_id == XED_REG_STACKPUSH) is_stackpush = 1;
else if (reg_id == XED_REG_STACKPOP) is_stackpop = 1;
if (-1 == regnum)
break;
else {
op_idx++;
eh->num_operands++;
eh->operand[op_idx].type = TRegister;
eh->operand[op_idx].addr = xed2chris_regmapping[reg_id][0];
eh->operand[op_idx].length =
(uint8_t) xed_decoded_inst_operand_length (&xedd, i);
eh->operand[op_idx].access = (uint8_t) xed_operand_rw (op);
eh->operand[op_idx].value = TEMU_cpu_regs[regnum];
switch (eh->operand[op_idx].addr) {
case ax_reg:
case bx_reg:
case cx_reg:
case dx_reg:
case bp_reg:
case sp_reg:
case si_reg:
case di_reg:
eh->operand[op_idx].value &= 0xFFFF;
break;
case al_reg:
case bl_reg:
case cl_reg:
case dl_reg:
eh->operand[op_idx].value &= 0xFF;
break;
case ah_reg:
case bh_reg:
case ch_reg:
case dh_reg:
eh->operand[op_idx].value = (eh->operand[i].value & 0xFF00) >> 8;
break;
default:
break;
}
}
if (ignore_taint == 0) set_operand_data(&(eh->operand[op_idx]));
break;
}
/* Immediate */
case XED_OPERAND_IMM0: {
op_idx++;
eh->num_operands++;
eh->operand[op_idx].type = TImmediate;
eh->operand[op_idx].length =
(uint8_t) xed_decoded_inst_operand_length (&xedd, i);
eh->operand[op_idx].access = (uint8_t) xed_operand_rw (op);
//xed_uint_t width = xed_decoded_inst_get_immediate_width(&xedd);
if (xed_decoded_inst_get_immediate_is_signed(&xedd)) {
xed_int32_t signed_imm_val =
xed_decoded_inst_get_signed_immediate(&xedd);
eh->operand[op_idx].value = (uint32_t) signed_imm_val;
}
else {
xed_uint64_t unsigned_imm_val =
xed_decoded_inst_get_unsigned_immediate(&xedd);
eh->operand[op_idx].value = (uint32_t) unsigned_imm_val;
}
break;
break;
}
/* Special immediate only used in ENTER instruction */
case XED_OPERAND_IMM1: {
op_idx++;
eh->num_operands++;
eh->operand[op_idx].type = TImmediate;
eh->operand[op_idx].length =
(uint8_t) xed_decoded_inst_operand_length (&xedd, i);
eh->operand[op_idx].access = (uint8_t) xed_operand_rw (op);
xed_uint8_t unsigned_imm_val =
xed_decoded_inst_get_second_immediate(&xedd);
eh->operand[op_idx].value = (uint32_t) unsigned_imm_val;
break;
}
/* Memory */
case XED_OPERAND_AGEN:
case XED_OPERAND_MEM0:
case XED_OPERAND_MEM1: {
unsigned long base = 0;
unsigned long index = 0;
unsigned long scale = 1;
unsigned long segbase = 0;
unsigned short segsel = 0;
unsigned long displacement = 0;
unsigned int j;
size_t remaining = 0;
/* Set memory index */
int mem_idx = 0;
if (op_name == XED_OPERAND_MEM1) mem_idx = 1;
unsigned int memlen = xed_decoded_inst_operand_length (&xedd, i);
for (j = 0; j < memlen; j+=4) {
/* Initialization */
base = 0;
index = 0;
scale = 1;
segbase = 0;
segsel = 0;
displacement = 0;
remaining = memlen - j;
op_idx++;
if(op_idx >= MAX_NUM_OPERANDS)
break;
//assert(op_idx < MAX_NUM_OPERANDS);
eh->num_operands++;
eh->operand[op_idx].type = TMemLoc;
eh->operand[op_idx].access = (uint8_t) xed_operand_rw (op);
eh->operand[op_idx].length =
remaining > 4 ? 4 : (uint8_t) remaining;
// Get Segment register
xed_reg_enum_t seg_regid =
xed_decoded_inst_get_seg_reg(&xedd,mem_idx);
if (seg_regid != XED_REG_INVALID) {
const xed_operand_values_t *xopv =
xed_decoded_inst_operands_const(&xedd);
xed_bool_t default_segment =
xed_operand_values_using_default_segment (xopv,mem_idx);
if (!default_segment) {
eh->num_operands++;
int segmentreg = xed2chris_regmapping[seg_regid][0] - 100;
segbase = TEMU_cpu_segs[segmentreg].base;
segsel = TEMU_cpu_segs[segmentreg].selector;
eh->memregs[op_idx][0].type = TRegister;
eh->memregs[op_idx][0].length = 2;
eh->memregs[op_idx][0].addr = xed2chris_regmapping[seg_regid][0];
eh->memregs[op_idx][0].access = (uint8_t) XED_OPERAND_ACTION_R;
eh->memregs[op_idx][0].value = segsel;
eh->memregs[op_idx][0].usage = memsegment;
if (ignore_taint == 0)
set_operand_data(&(eh->memregs[op_idx][0]));
int dt;
if (segsel & 0x4) // ldt
dt = TEMU_cpu_ldt->base;
else //gdt
dt = TEMU_cpu_gdt->base;
segsel = segsel >> 3;
unsigned long segent = dt + 8 * segsel;
unsigned char segdes[8];
TEMU_read_mem(segent, 8, segdes);
#if 0
// debugging code to double check segbase value
unsigned long segbasenew = segdes[2] + segdes[3] * 256 +
segdes[4] * 256 * 256 + segdes[7] * 256 * 256 * 256;
if (segbase != segbasenew) {
term_printf("segbase unexpected: 0x%08lX v.s 0x%08lX\n",
segbase, segbasenew);
}
#endif
/* Segment descriptor is stored as a memory operand */
eh->num_operands+=2;
eh->memregs[op_idx][3].type = TMemLoc;
eh->memregs[op_idx][3].length = 4;
eh->memregs[op_idx][3].addr = segent;
eh->memregs[op_idx][3].access =
(uint8_t) XED_OPERAND_ACTION_INVALID;
eh->memregs[op_idx][3].value = *(uint32_t *) segdes;
eh->memregs[op_idx][3].tainted = 0;
eh->memregs[op_idx][3].usage = memsegent0;
eh->memregs[op_idx][4].type = TMemLoc;
eh->memregs[op_idx][4].length = 4;
eh->memregs[op_idx][4].addr = segent + 4;
eh->memregs[op_idx][4].access =
(uint8_t) XED_OPERAND_ACTION_INVALID;
eh->memregs[op_idx][4].value = *(uint32_t *) (segdes + 4);
eh->memregs[op_idx][4].tainted = 0;
eh->memregs[op_idx][4].usage = memsegent1;
}
}
// Get Base register
xed_reg_enum_t base_regid =
xed_decoded_inst_get_base_reg(&xedd,mem_idx);
if (base_regid != XED_REG_INVALID) {
eh->num_operands++;
int basereg = xed2chris_regmapping[base_regid][1];
base = TEMU_cpu_regs[basereg];
eh->memregs[op_idx][1].type = TRegister;
eh->memregs[op_idx][1].addr = xed2chris_regmapping[base_regid][0];
eh->memregs[op_idx][1].length = 4;
eh->memregs[op_idx][1].access = (uint8_t) XED_OPERAND_ACTION_R;
eh->memregs[op_idx][1].value = base;
eh->memregs[op_idx][1].usage = membase;
if (ignore_taint == 0) set_operand_data(&(eh->memregs[op_idx][1]));
}
// Get Index register and Scale
xed_reg_enum_t index_regid =
xed_decoded_inst_get_index_reg(&xedd,mem_idx);
if (mem_idx == 0 && index_regid != XED_REG_INVALID) {
eh->num_operands++;
int indexreg = xed2chris_regmapping[index_regid][1];
index = TEMU_cpu_regs[indexreg];
eh->memregs[op_idx][2].type = TRegister;
eh->memregs[op_idx][2].addr = xed2chris_regmapping[index_regid][0];
eh->memregs[op_idx][2].length = 4;
eh->memregs[op_idx][2].access = (uint8_t) XED_OPERAND_ACTION_R;
eh->memregs[op_idx][2].value = index;
eh->memregs[op_idx][2].usage = memindex;
if (ignore_taint == 0) set_operand_data(&(eh->memregs[op_idx][2]));
// Get Scale (AKA width) (only have a scale if the index exists)
if (xed_decoded_inst_get_scale(&xedd,i) != 0) {
scale = (unsigned long) xed_decoded_inst_get_scale(&xedd,mem_idx);
}
}
// Get displacement (AKA offset)
displacement =
(unsigned long) xed_decoded_inst_get_memory_displacement
(&xedd,mem_idx);
// Fix displacement for:
// 1) Any instruction that pushes into the stack, since ESP is
// decremented before memory operand is written using ESP.
// Affects: ENTER,PUSH,PUSHA,PUSHF,CALL
if (is_stackpush) {
stackpushpop_acc += eh->operand[op_idx].length;
displacement = displacement - stackpushpop_acc -j;
}
// 2) Pop instructions where the
// destination operand is a memory location that uses ESP
// as base or index register.
// The pop operations increments ESP and the written memory
// location address needs to be adjusted.
// Affects: pop (%esp)
else if ((category == XED_CATEGORY_POP) && (!is_stackpop)) {
if ((eh->memregs[op_idx][1].addr == esp_reg) ||
(eh->memregs[op_idx][2].addr == esp_reg))
{
displacement = displacement + eh->operand[op_idx].length;
}
}
// Calculate memory address accessed
eh->operand[op_idx].addr =
j + segbase + base + index * scale + displacement;
// Special handling for LEA instructions
if (op_name == XED_OPERAND_AGEN) {
eh->operand[op_idx].type = TMemAddress;
eh->operand[op_idx].length = 4;
has_page_fault = 0; // LEA won't trigger page fault
}
else {
has_page_fault = TEMU_read_mem(eh->operand[op_idx].addr,
(int)(eh->operand[op_idx].length),
(uint8_t *)&(eh->operand[op_idx].value));
}
// Check if instruction accesses user memory
// kernel_mem_start defined in shared/read_linux.c
if ((eh->operand[op_idx].addr < kernel_mem_start) &&
(op_name != XED_OPERAND_AGEN))
{
access_user_mem = 1;
}
if (ignore_taint == 0) set_operand_data(&(eh->operand[op_idx]));
}
break;
}
/* Jumps */
case XED_OPERAND_PTR: // pointer (always in conjunction with a IMM0)
case XED_OPERAND_RELBR: { // branch displacements
xed_uint_t disp = xed_decoded_inst_get_branch_displacement(&xedd);
/* Displacement is from instruction end */
/* Adjust displacement with instruction size */
disp = disp + eh->inst_size;
op_idx++;
eh->num_operands++;
eh->operand[op_idx].type = TJump;
eh->operand[op_idx].length = 4;
eh->operand[op_idx].access = (uint8_t) xed_operand_rw (op);
eh->operand[op_idx].value = disp;
break;
}
/* Floating point registers */
case XED_REG_X87CONTROL:
case XED_REG_X87STATUS:
case XED_REG_X87TOP:
case XED_REG_X87TAG:
case XED_REG_X87PUSH:
case XED_REG_X87POP:
case XED_REG_X87POP2:
op_idx++;
eh->num_operands++;
eh->operand[op_idx].type = TFloatRegister;
eh->operand[op_idx].length = 4;
eh->operand[op_idx].access = (uint8_t) xed_operand_rw (op);
default:
break;
}
}
void print_operands(xed_decoded_inst_t* xedd) {
unsigned int i, noperands;
cout << "Operands" << endl;
const xed_inst_t* xi = xed_decoded_inst_inst(xedd);
noperands = xed_inst_noperands(xi);
for( i=0; i < noperands ; i++) {
const xed_operand_t* op = xed_inst_operand(xi,i);
xed_operand_enum_t op_name = xed_operand_name(op);
cout << i << " " << xed_operand_enum_t2str(op_name) << " ";
switch(op_name) {
case XED_OPERAND_AGEN:
case XED_OPERAND_MEM0:
case XED_OPERAND_MEM1:
// we print memops in a different function
break;
case XED_OPERAND_PTR: // pointer (always in conjunction with a IMM0)
case XED_OPERAND_RELBR: { // branch displacements
xed_uint_t disp_bits = xed_decoded_inst_get_branch_displacement_width(xedd);
if (disp_bits) {
//cout << "BRANCH_DISPLACEMENT_BYTES= " << disp_bits << " ";
xed_int32_t disp = xed_decoded_inst_get_branch_displacement(xedd);
//cout << hex << setfill('0') << setw(8) << disp << setfill(' ') << dec;
}
}
break;
case XED_OPERAND_IMM0: { // immediates
xed_uint_t width = xed_decoded_inst_get_immediate_width(xedd);
if (xed_decoded_inst_get_immediate_is_signed(xedd)) {
xed_int32_t x =xed_decoded_inst_get_signed_immediate(xedd);
//cout << hex << setfill('0') << setw(8) << x << setfill(' ') << dec
// << '(' << width << ')';
}
else {
xed_uint64_t x = xed_decoded_inst_get_unsigned_immediate(xedd);
//cout << hex << setfill('0') << setw(16) << x << setfill(' ') << dec
// << '(' << width << ')';
}
break;
}
case XED_OPERAND_IMM1: { // immediates
xed_uint8_t x = xed_decoded_inst_get_second_immediate(xedd);
//cout << hex << setfill('0') << setw(2) << (int)x << setfill(' ') << dec;
break;
}
case XED_OPERAND_REG0:
case XED_OPERAND_REG1:
case XED_OPERAND_REG2:
case XED_OPERAND_REG3:
case XED_OPERAND_REG4:
case XED_OPERAND_REG5:
case XED_OPERAND_REG6:
case XED_OPERAND_REG7:
case XED_OPERAND_REG8:
case XED_OPERAND_REG9:
case XED_OPERAND_REG10:
case XED_OPERAND_REG11:
case XED_OPERAND_REG12:
case XED_OPERAND_REG13:
case XED_OPERAND_REG14:
case XED_OPERAND_REG15: {
xed_reg_enum_t r = xed_decoded_inst_get_reg(xedd, op_name);
cout << xed_operand_enum_t2str(op_name) << "=" << xed_reg_enum_t2str(r);
break;
}
default:
//cout << "[Not currently printing value of field " << xed_operand_enum_t2str(op_name) << ']';
break;
}
//cout << " " << xed_operand_visibility_enum_t2str(xed_operand_operand_visibility(op))
// << " / " << xed_operand_action_enum_t2str(xed_operand_rw(op))
// << " / " << xed_operand_width_enum_t2str(xed_operand_width(op));
//cout << " bytes=" << xed_decoded_inst_operand_length(xedd,i);
//cout << endl;
}
}
void OfflineX86Code::disasm(FILE* file,
TCA fileStartAddr,
TCA codeStartAddr,
uint64_t codeLen,
const PerfEventsMap<TCA>& perfEvents,
BCMappingInfo bcMappingInfo,
bool printAddr /* =true */,
bool printBinary /* =false */) {
char codeStr[MAX_INSTR_ASM_LEN];
xed_uint8_t* code = (xed_uint8_t*) alloca(codeLen);
xed_uint8_t* frontier;
TCA ip;
TCA r10val = 0;
size_t currBC = 0;
if (codeLen == 0) return;
auto const offset = codeStartAddr - fileStartAddr;
if (fseek(file, offset, SEEK_SET)) {
error("disasm error: seeking file");
}
size_t readLen = fread(code, codeLen, 1, file);
if (readLen != 1) {
error("Failed to read {} bytes at offset {} from code file due to {}",
codeLen, offset, feof(file) ? "EOF" : "read error");
}
xed_decoded_inst_t xedd;
// Decode and print each instruction
for (frontier = code, ip = codeStartAddr; frontier < code + codeLen; ) {
xed_decoded_inst_zero_set_mode(&xedd, &xed_state);
xed_decoded_inst_set_input_chip(&xedd, XED_CHIP_INVALID);
xed_error_enum_t xed_error = xed_decode(&xedd, frontier, 15);
if (xed_error != XED_ERROR_NONE) break;
// Get disassembled instruction in codeStr
if (!xed_format_context(xed_syntax, &xedd, codeStr,
MAX_INSTR_ASM_LEN, (uint64_t)ip, nullptr
#if XED_ENCODE_ORDER_MAX_ENTRIES != 28 // Newer version of XED library
, 0
#endif
)) {
error("disasm error: xed_format_context failed");
}
// Annotate the x86 with its bytecode.
currBC = printBCMapping(bcMappingInfo, currBC, (TCA)ip);
if (printAddr) printf("%14p: ", ip);
uint32_t instrLen = xed_decoded_inst_get_length(&xedd);
if (printBinary) {
uint32_t i;
for (i=0; i < instrLen; i++) {
printf("%02X", frontier[i]);
}
for (; i < 16; i++) {
printf(" ");
}
}
// For calls, we try to figure out the destination symbol name.
// We look both at relative branches and the pattern:
// move r10, IMMEDIATE
// call r10
xed_iclass_enum_t iclass = xed_decoded_inst_get_iclass(&xedd);
string callDest = "";
if (iclass == XED_ICLASS_CALL_NEAR || iclass == XED_ICLASS_CALL_FAR) {
const xed_inst_t *xi = xed_decoded_inst_inst(&xedd);
always_assert(xed_inst_noperands(xi) >= 1);
const xed_operand_t *opnd = xed_inst_operand(xi, 0);
xed_operand_enum_t opndName = xed_operand_name(opnd);
if (opndName == XED_OPERAND_RELBR) {
if (xed_decoded_inst_get_branch_displacement_width(&xedd)) {
xed_int32_t disp = xed_decoded_inst_get_branch_displacement(&xedd);
TCA addr = ip + instrLen + disp;
callDest = getSymbolName(addr);
}
} else if (opndName == XED_OPERAND_REG0) {
if (xed_decoded_inst_get_reg(&xedd, opndName) == XED_REG_R10) {
callDest = getSymbolName(r10val);
}
}
} else if (iclass == XED_ICLASS_MOV) {
// Look for moves into r10 and keep r10val updated
const xed_inst_t* xi = xed_decoded_inst_inst(&xedd);
always_assert(xed_inst_noperands(xi) >= 2);
const xed_operand_t *destOpnd = xed_inst_operand(xi, 0);
xed_operand_enum_t destOpndName = xed_operand_name(destOpnd);
if (destOpndName == XED_OPERAND_REG0 &&
xed_decoded_inst_get_reg(&xedd, destOpndName) == XED_REG_R10) {
const xed_operand_t *srcOpnd = xed_inst_operand(xi, 1);
xed_operand_enum_t srcOpndName = xed_operand_name(srcOpnd);
if (srcOpndName == XED_OPERAND_IMM0) {
TCA addr = (TCA)xed_decoded_inst_get_unsigned_immediate(&xedd);
r10val = addr;
}
}
}
if (!perfEvents.empty()) {
printEventStats((TCA)ip, instrLen, perfEvents);
} else {
printf("%48s", "");
}
printf("%s%s\n", codeStr, callDest.c_str());
frontier += instrLen;
ip += instrLen;
}
}
