准备

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Intel Pin 下载 编译 运行
略.详见 Intel Pin README.

源码

debugtrace.c

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/*
* Copyright (C) 2004-2021 Intel Corporation.
* SPDX-License-Identifier: MIT
*/

/*! @file
* This file contains a tool that generates instructions traces with values.
* It is designed to help debugging.
*/

#include <vector>
#include <iostream>
#include <iomanip>
#include <fstream>
#include <unistd.h>
#include "pin.H"
#include "instlib.H"
#include "control_manager.H"
#include "regvalue_utils.h"

using namespace CONTROLLER;
using namespace INSTLIB;

struct kv_t
{
const char *function;
size_t address;
};

/* ===================================================================== */
/* Commandline Switches */
/* ===================================================================== */

KNOB< string > KnobOutputFile(KNOB_MODE_WRITEONCE, "pintool", "o", "debugtrace.out", "trace file");
KNOB< BOOL > KnobPid(KNOB_MODE_WRITEONCE, "pintool", "i", "0", "append pid to output");
KNOB< THREADID > KnobWatchThread(KNOB_MODE_WRITEONCE, "pintool", "watch_thread", "-1", "thread to watch, -1 for all");
KNOB< BOOL > KnobFlush(KNOB_MODE_WRITEONCE, "pintool", "flush", "0", "Flush output after every instruction");
KNOB< BOOL > KnobSymbols(KNOB_MODE_WRITEONCE, "pintool", "symbols", "1", "Include symbol information");
KNOB< BOOL > KnobLines(KNOB_MODE_WRITEONCE, "pintool", "lines", "0", "Include line number information");
KNOB< BOOL > KnobTraceInstructions(KNOB_MODE_WRITEONCE, "pintool", "instruction", "0", "Trace instructions");
KNOB< BOOL > KnobTraceCalls(KNOB_MODE_WRITEONCE, "pintool", "call", "1", "Trace calls");
KNOB< BOOL > KnobTraceMemory(KNOB_MODE_WRITEONCE, "pintool", "memory", "0", "Trace memory");
KNOB< BOOL > KnobSilent(KNOB_MODE_WRITEONCE, "pintool", "silent", "0", "Do everything but write file (for debugging).");
KNOB< BOOL > KnobEarlyOut(KNOB_MODE_WRITEONCE, "pintool", "early_out", "0", "Exit after tracing the first region.");

/* ===================================================================== */

INT32 Usage()
{
cerr << "This pin tool collects an instruction trace for debugging\n"
"\n";

cerr << KNOB_BASE::StringKnobSummary();

cerr << endl;

return -1;
}

/* ===================================================================== */
/* Global Variables */
/* ===================================================================== */

static std::ofstream out;

static INT32 enabled = 0;

static FILTER filter;

static ICOUNT icount;

static BOOL Emit(THREADID threadid)
{
if (!enabled || KnobSilent || (KnobWatchThread != static_cast< THREADID >(-1) && KnobWatchThread != threadid)) return false;
return true;
}

static VOID Flush()
{
if (KnobFlush) out << flush;
}

/* ===================================================================== */

static VOID Fini(int, VOID* v);

static VOID Handler(EVENT_TYPE ev, VOID*, CONTEXT* ctxt, VOID*, THREADID, bool bcast)
{
switch (ev)
{
case EVENT_START:
enabled = 1;
PIN_RemoveInstrumentation();
#if defined(TARGET_IA32) || defined(TARGET_IA32E)
// So that the rest of the current trace is re-instrumented.
if (ctxt) PIN_ExecuteAt(ctxt);
#endif
break;

case EVENT_STOP:
enabled = 0;
PIN_RemoveInstrumentation();
if (KnobEarlyOut)
{
cerr << "Exiting due to -early_out" << endl;
Fini(0, NULL);
exit(0);
}
#if defined(TARGET_IA32) || defined(TARGET_IA32E)
// So that the rest of the current trace is re-instrumented.
if (ctxt) PIN_ExecuteAt(ctxt);
#endif
break;

default:
ASSERTX(false);
}
}

/* ===================================================================== */

VOID EmitNoValues(THREADID threadid, string* str)
{
if (!Emit(threadid)) return;

out << *str << endl;

Flush();
}

VOID Emit1Values(THREADID threadid, string* str, string* reg1str, ADDRINT reg1val)
{
if (!Emit(threadid)) return;

out << *str << " | " << *reg1str << " = " << reg1val << endl;

Flush();
}

VOID Emit2Values(THREADID threadid, string* str, string* reg1str, ADDRINT reg1val, string* reg2str, ADDRINT reg2val)
{
if (!Emit(threadid)) return;

out << *str << " | " << *reg1str << " = " << reg1val << ", " << *reg2str << " = " << reg2val << endl;

Flush();
}

VOID Emit3Values(THREADID threadid, string* str, string* reg1str, ADDRINT reg1val, string* reg2str, ADDRINT reg2val,
string* reg3str, ADDRINT reg3val)
{
if (!Emit(threadid)) return;

out << *str << " | " << *reg1str << " = " << reg1val << ", " << *reg2str << " = " << reg2val << ", " << *reg3str << " = "
<< reg3val << endl;

Flush();
}

VOID Emit4Values(THREADID threadid, string* str, string* reg1str, ADDRINT reg1val, string* reg2str, ADDRINT reg2val,
string* reg3str, ADDRINT reg3val, string* reg4str, ADDRINT reg4val)
{
if (!Emit(threadid)) return;

out << *str << " | " << *reg1str << " = " << reg1val << ", " << *reg2str << " = " << reg2val << ", " << *reg3str << " = "
<< reg3val << ", " << *reg4str << " = " << reg4val << endl;

Flush();
}

const UINT32 MaxEmitArgs = 4;

AFUNPTR emitFuns[] = {AFUNPTR(EmitNoValues), AFUNPTR(Emit1Values), AFUNPTR(Emit2Values), AFUNPTR(Emit3Values),
AFUNPTR(Emit4Values)};

/* ===================================================================== */

VOID EmitXMM(THREADID threadid, UINT32 regno, PINTOOL_REGISTER* xmm)
{
if (!Emit(threadid)) return;
out << "\t\t\tXMM" << dec << regno << " := " << setfill('0') << hex;
out.unsetf(ios::showbase);
for (int i = 0; i < 16; i++)
{
if (i == 4 || i == 8 || i == 12) out << "_";
out << setw(2) << (int)xmm->byte[15 - i]; // msb on the left as in registers
}
out << setfill(' ') << endl;
out.setf(ios::showbase);
Flush();
}

VOID AddXMMEmit(INS ins, IPOINT point, REG xmm_dst)
{
INS_InsertCall(ins, point, AFUNPTR(EmitXMM), IARG_THREAD_ID, IARG_UINT32, xmm_dst - REG_XMM0, IARG_REG_CONST_REFERENCE,
xmm_dst, IARG_END);
}

VOID AddEmit(INS ins, IPOINT point, string& traceString, UINT32 regCount, REG regs[])
{
if (regCount > MaxEmitArgs) regCount = MaxEmitArgs;

IARGLIST args = IARGLIST_Alloc();
for (UINT32 i = 0; i < regCount; i++)
{
IARGLIST_AddArguments(args, IARG_PTR, new string(REG_StringShort(regs[i])), IARG_REG_VALUE, regs[i], IARG_END);
}

INS_InsertCall(ins, point, emitFuns[regCount], IARG_THREAD_ID, IARG_PTR, new string(traceString), IARG_IARGLIST, args,
IARG_END);
IARGLIST_Free(args);
}

static VOID* WriteEa[PIN_MAX_THREADS];

VOID CaptureWriteEa(THREADID threadid, VOID* addr) { WriteEa[threadid] = addr; }

VOID ShowN(UINT32 n, VOID* ea)
{
out.unsetf(ios::showbase);
// Print out the bytes in "big endian even though they are in memory little endian.
// This is most natural for 8B and 16B quantities that show up most frequently.
// The address pointed to
out << std::setfill('0');
UINT8 b[512];
UINT8* x;
if (n > 512)
x = new UINT8[n];
else
x = b;
PIN_SafeCopy(x, static_cast< UINT8* >(ea), n);
for (UINT32 i = 0; i < n; i++)
{
out << std::setw(2) << static_cast< UINT32 >(x[n - i - 1]);
if (((reinterpret_cast< ADDRINT >(ea) + n - i - 1) & 0x3) == 0 && i < n - 1) out << "_";
}
out << std::setfill(' ');
out.setf(ios::showbase);
if (n > 512) delete[] x;
}

VOID EmitWrite(THREADID threadid, UINT32 size)
{
if (!Emit(threadid)) return;

out << " Write ";

VOID* ea = WriteEa[threadid];

switch (size)
{
case 0:
out << "0 repeat count" << endl;
break;

case 1:
{
UINT8 x;
PIN_SafeCopy(&x, static_cast< UINT8* >(ea), 1);
out << "*(UINT8*)" << ea << " = " << static_cast< UINT32 >(x) << endl;
}
break;

case 2:
{
UINT16 x;
PIN_SafeCopy(&x, static_cast< UINT16* >(ea), 2);
out << "*(UINT16*)" << ea << " = " << x << endl;
}
break;

case 4:
{
UINT32 x;
PIN_SafeCopy(&x, static_cast< UINT32* >(ea), 4);
out << "*(UINT32*)" << ea << " = " << x << endl;
}
break;

case 8:
{
UINT64 x;
PIN_SafeCopy(&x, static_cast< UINT64* >(ea), 8);
out << "*(UINT64*)" << ea << " = " << x << endl;
}
break;

default:
out << "*(UINT" << dec << size * 8 << hex << ")" << ea << " = ";
ShowN(size, ea);
out << endl;
break;
}

Flush();
}

VOID EmitRead(THREADID threadid, VOID* ea, UINT32 size)
{
if (!Emit(threadid)) return;

out << " Read ";

switch (size)
{
case 0:
out << "0 repeat count" << endl;
break;

case 1:
{
UINT8 x;
PIN_SafeCopy(&x, static_cast< UINT8* >(ea), 1);
out << static_cast< UINT32 >(x) << " = *(UINT8*)" << ea << endl;
}
break;

case 2:
{
UINT16 x;
PIN_SafeCopy(&x, static_cast< UINT16* >(ea), 2);
out << x << " = *(UINT16*)" << ea << endl;
}
break;

case 4:
{
UINT32 x;
PIN_SafeCopy(&x, static_cast< UINT32* >(ea), 4);
out << x << " = *(UINT32*)" << ea << endl;
}
break;

case 8:
{
UINT64 x;
PIN_SafeCopy(&x, static_cast< UINT64* >(ea), 8);
out << x << " = *(UINT64*)" << ea << endl;
}
break;

default:
ShowN(size, ea);
out << " = *(UINT" << dec << size * 8 << hex << ")" << ea << endl;
break;
}

Flush();
}

static INT32 indent = 0;

VOID Indent()
{
for (INT32 i = 0; i < indent; i++)
{
out << "| ";
}
}

VOID EmitICount()
{
//out << setw(10) << dec << icount.Count() << hex << " ";
}

VOID EmitDirectCall(THREADID threadid, string* str, INT32 tailCall, ADDRINT arg0, ADDRINT arg1)
{
if (!Emit(threadid)) return;

EmitICount();

if (tailCall)
{
// A tail call is like an implicit return followed by an immediate call
indent--;
}

Indent();
out << *str << "(" << arg0 << ", " << arg1 << ", ...)" << endl;

indent++;

Flush();
}

string FormatAddress(ADDRINT address, RTN rtn)
{
string s;// = StringFromAddrint(address);
if (KnobSymbols && RTN_Valid(rtn))
{
//IMG img = SEC_Img(RTN_Sec(rtn));
//s += " ";
//if (IMG_Valid(img))
//{
// s += IMG_Name(img) + ":";
//}
//s += RTN_Name(rtn);
////////// C++filt //////////////
//string api = "c++filt ";
//api += RTN_Name(rtn);
//FILE *api_file = popen(api.c_str(), "r");
//char buff[1024];
//fgets(buff, sizeof(buff), api_file);
//pclose(api_file);
//buff[strlen(buff)-1] = '\0';
//s+=buff;
////////////////////////

INT32 line;
string file;
PIN_GetSourceLocation(RTN_Address(rtn), NULL, &line, &file);
if(!file.empty())
{
char buff[1024];
snprintf(buff, sizeof(buff), "%s", file.c_str());
char *p = basename(buff);
s += p;
s += ":";
}

s += RTN_Name(rtn);

ADDRINT delta = address - RTN_Address(rtn);
if (delta != 0)
{
s += "+" + hexstr(delta, 2);
//s += "+" + delta;
}
}

if (KnobLines)
{
INT32 line;
string file;

PIN_GetSourceLocation(address, NULL, &line, &file);
if (file != "")
{
s += " (" + file + ":" + decstr(line) + ")";
}
//cout << "address "<< hex << address << " file " << file << " line "<< dec << line << endl;
}
return s;
}

VOID EmitIndirectCall(THREADID threadid, string* str, ADDRINT target, ADDRINT arg0, ADDRINT arg1)
{
if (!Emit(threadid)) return;

EmitICount();
Indent();
out << *str;

PIN_LockClient();

string s = FormatAddress(target, RTN_FindByAddress(target));

PIN_UnlockClient();

out << s << "(" << arg0 << ", " << arg1 << ", ...)" << endl;
indent++;

Flush();
}

VOID EmitReturn(THREADID threadid, string* str, ADDRINT ret0)
{
if (!Emit(threadid)) return;

EmitICount();
indent--;
if (indent < 0)
{
out << "@@@ return underflow\n";
indent = 0;
}

Indent();
out << *str << " returns: " << ret0 << endl;

Flush();
}

VOID CallTrace(TRACE trace, INS ins)
{
if (!KnobTraceCalls) return;

if (INS_IsCall(ins) && !INS_IsDirectControlFlow(ins))
{
// Indirect call
string s = "Call " + FormatAddress(INS_Address(ins), TRACE_Rtn(trace));
s += " -> ";

INS_InsertCall(ins, IPOINT_BEFORE, AFUNPTR(EmitIndirectCall), IARG_THREAD_ID, IARG_PTR, new string(s),
IARG_BRANCH_TARGET_ADDR, IARG_FUNCARG_CALLSITE_VALUE, 0, IARG_FUNCARG_CALLSITE_VALUE, 1, IARG_END);
}
else if (INS_IsDirectControlFlow(ins))
{
// Is this a tail call?
RTN sourceRtn = TRACE_Rtn(trace);
RTN destRtn = RTN_FindByAddress(INS_DirectControlFlowTargetAddress(ins));

if (INS_IsCall(ins) // conventional call
|| sourceRtn != destRtn // tail call
)
{
BOOL tailcall = !INS_IsCall(ins);

string s = "";
if (tailcall)
{
s += "Tailcall ";
}
else
{
if (INS_IsProcedureCall(ins))
s += "CALL ";
else
{
s += "PcMaterialization ";
tailcall = 1;
}
}

//s += INS_Mnemonic(ins) + " ";

s += FormatAddress(INS_Address(ins), TRACE_Rtn(trace));
s += " -> ";

ADDRINT target = INS_DirectControlFlowTargetAddress(ins);

s += FormatAddress(target, RTN_FindByAddress(target));

INS_InsertCall(ins, IPOINT_BEFORE, AFUNPTR(EmitDirectCall), IARG_THREAD_ID, IARG_PTR, new string(s), IARG_BOOL,
tailcall, IARG_FUNCARG_CALLSITE_VALUE, 0, IARG_FUNCARG_CALLSITE_VALUE, 1, IARG_END);
}
}
else if (INS_IsRet(ins))
{
RTN rtn = TRACE_Rtn(trace);

#if defined(TARGET_LINUX) && defined(TARGET_IA32)
// if( RTN_Name(rtn) == "_dl_debug_state") return;
if (RTN_Valid(rtn) && RTN_Name(rtn) == "_dl_runtime_resolve") return;
#endif
string tracestring = "Return " + FormatAddress(INS_Address(ins), rtn);
INS_InsertCall(ins, IPOINT_BEFORE, AFUNPTR(EmitReturn), IARG_THREAD_ID, IARG_PTR, new string(tracestring),
IARG_FUNCRET_EXITPOINT_VALUE, IARG_END);
}
}

VOID InstructionTrace(TRACE trace, INS ins)
{
if (!KnobTraceInstructions) return;

ADDRINT addr = INS_Address(ins);
ASSERTX(addr);

// Format the string at instrumentation time
string traceString = "";
string astring = FormatAddress(INS_Address(ins), TRACE_Rtn(trace));
for (INT32 length = astring.length(); length < 30; length++)
{
traceString += " ";
}
traceString = astring + traceString;

traceString += " " + INS_Disassemble(ins);

for (INT32 length = traceString.length(); length < 80; length++)
{
traceString += " ";
}

INT32 regCount = 0;
REG regs[20];
REG xmm_dst = REG_INVALID();

for (UINT32 i = 0; i < INS_MaxNumWRegs(ins); i++)
{
REG x = REG_FullRegName(INS_RegW(ins, i));

if (REG_is_gr(x)
#if defined(TARGET_IA32)
|| x == REG_EFLAGS
#elif defined(TARGET_IA32E)
|| x == REG_RFLAGS
#endif
)
{
regs[regCount] = x;
regCount++;
}

if (REG_is_xmm(x)) xmm_dst = x;
}

if (INS_IsValidForIpointAfter(ins))
{
AddEmit(ins, IPOINT_AFTER, traceString, regCount, regs);
}
if (INS_IsValidForIpointTakenBranch(ins))
{
AddEmit(ins, IPOINT_TAKEN_BRANCH, traceString, regCount, regs);
}

if (xmm_dst != REG_INVALID())
{
if (INS_IsValidForIpointAfter(ins)) AddXMMEmit(ins, IPOINT_AFTER, xmm_dst);
if (INS_IsValidForIpointTakenBranch(ins)) AddXMMEmit(ins, IPOINT_TAKEN_BRANCH, xmm_dst);
}
}

VOID MemoryTrace(INS ins)
{
if (!KnobTraceMemory) return;

if (INS_IsMemoryWrite(ins) && INS_IsStandardMemop(ins))
{
INS_InsertCall(ins, IPOINT_BEFORE, AFUNPTR(CaptureWriteEa), IARG_THREAD_ID, IARG_MEMORYWRITE_EA, IARG_END);

if (INS_IsValidForIpointAfter(ins))
{
INS_InsertPredicatedCall(ins, IPOINT_AFTER, AFUNPTR(EmitWrite), IARG_THREAD_ID, IARG_MEMORYWRITE_SIZE, IARG_END);
}
if (INS_IsValidForIpointTakenBranch(ins))
{
INS_InsertPredicatedCall(ins, IPOINT_TAKEN_BRANCH, AFUNPTR(EmitWrite), IARG_THREAD_ID, IARG_MEMORYWRITE_SIZE,
IARG_END);
}
}

if (INS_HasMemoryRead2(ins) && INS_IsStandardMemop(ins))
{
INS_InsertPredicatedCall(ins, IPOINT_BEFORE, AFUNPTR(EmitRead), IARG_THREAD_ID, IARG_MEMORYREAD2_EA, IARG_MEMORYREAD_SIZE,
IARG_END);
}

if (INS_IsMemoryRead(ins) && !INS_IsPrefetch(ins) && INS_IsStandardMemop(ins))
{
INS_InsertPredicatedCall(ins, IPOINT_BEFORE, AFUNPTR(EmitRead), IARG_THREAD_ID, IARG_MEMORYREAD_EA, IARG_MEMORYREAD_SIZE,
IARG_END);
}
}

/* ===================================================================== */

VOID Trace(TRACE trace, VOID* v)
{
if (!filter.SelectTrace(trace)) return;

if (enabled)
{
for (BBL bbl = TRACE_BblHead(trace); BBL_Valid(bbl); bbl = BBL_Next(bbl))
{
for (INS ins = BBL_InsHead(bbl); INS_Valid(ins); ins = INS_Next(ins))
{
InstructionTrace(trace, ins);

CallTrace(trace, ins);

MemoryTrace(ins);
}
}
}
}

/* ===================================================================== */

VOID Fini(int, VOID* v)
{
out << "# $eof" << endl;

out.close();
}

/* ===================================================================== */

static void OnSig(THREADID threadIndex, CONTEXT_CHANGE_REASON reason, const CONTEXT* ctxtFrom, CONTEXT* ctxtTo, INT32 sig,
VOID* v)
{
if (ctxtFrom != 0)
{
ADDRINT address = PIN_GetContextReg(ctxtFrom, REG_INST_PTR);
out << "SIG signal=" << sig << " on thread " << threadIndex << " at address " << hex << address << dec << " ";
}

switch (reason)
{
case CONTEXT_CHANGE_REASON_FATALSIGNAL:
out << "FATALSIG" << sig;
break;
case CONTEXT_CHANGE_REASON_SIGNAL:
out << "SIGNAL " << sig;
break;
case CONTEXT_CHANGE_REASON_SIGRETURN:
out << "SIGRET";
break;

case CONTEXT_CHANGE_REASON_APC:
out << "APC";
break;

case CONTEXT_CHANGE_REASON_EXCEPTION:
out << "EXCEPTION";
break;

case CONTEXT_CHANGE_REASON_CALLBACK:
out << "CALLBACK";
break;

default:
break;
}
out << std::endl;
}

/* ===================================================================== */

static CONTROL_MANAGER control;
static SKIPPER skipper;

/* ===================================================================== */

int main(int argc, CHAR* argv[])
{
PIN_InitSymbols();

if (PIN_Init(argc, argv))
{
return Usage();
}

string filename = KnobOutputFile.Value();

if (KnobPid)
{
filename += "." + decstr(getpid());
}

// Do this before we activate controllers
out.open(filename.c_str());
out << hex << right;
out.setf(ios::showbase);

control.RegisterHandler(Handler, 0, FALSE);
control.Activate();
skipper.CheckKnobs(0);

TRACE_AddInstrumentFunction(Trace, 0);
PIN_AddContextChangeFunction(OnSig, 0);

PIN_AddFiniFunction(Fini, 0);

filter.Activate();
icount.Activate();

// Never returns

PIN_StartProgram();

return 0;
}

/* ===================================================================== */
/* eof */
/* ===================================================================== */

test_main.c

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#include<stdio.h>
void printdisk(char x,char y) /*定义打印函数*/
{
printf("%c----->%c\n",x,y);
}
void hanoi(int n,char a,char b,char c) /*定义递归函数hanoi()完成移动*/
{
if(n==1) /*如果A针上的盘子数只剩下最后一个,移到C针上*/
printdisk(a,c);
else /*如果A针上的盘子数多于一个,执行以下语句*/
{
hanoi(n-1,a,c,b); /*将A针上的n-1个盘子借助C针先移到B针上*/
printdisk(a,c); /*将A针上剩下的一个盘子移到C针上,即打印移动方式*/
hanoi(n-1,b,a,c); /*将n-1个盘从B针借助A针移到C针上*/
}
}
int main()
{
int n = 4;
hanoi(n,'A','B','C'); /*调用hanoi()函数*/
}

编译运行

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gcc -g -O0 han.c && ./a.out
pin -t ~/debugtrace.so -- ./a.out

追踪效果