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trace.c
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trace.c
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/*
*
* honggfuzz - architecture dependent code (LINUX/PTRACE)
* -----------------------------------------
*
* Author: Robert Swiecki <swiecki@google.com>
*
* Copyright 2010-2018 by Google Inc. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License"); you may
* not use this file except in compliance with the License. You may obtain
* a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
* implied. See the License for the specific language governing
* permissions and limitations under the License.
*
*/
#include "linux/trace.h"
#include <ctype.h>
#include <dirent.h>
#include <elf.h>
#include <endian.h>
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#if defined(__GLIBC__)
#include <sys/cdefs.h>
#endif
#include <sys/personality.h>
#include <sys/ptrace.h>
#include <sys/resource.h>
#include <sys/stat.h>
#include <sys/syscall.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/uio.h>
#include <sys/user.h>
#include <sys/wait.h>
#include <time.h>
#include <unistd.h>
#include "libhfcommon/common.h"
#include "libhfcommon/files.h"
#include "libhfcommon/log.h"
#include "libhfcommon/util.h"
#include "linux/bfd.h"
#include "linux/unwind.h"
#include "report.h"
#include "sanitizers.h"
#include "socketfuzzer.h"
#include "subproc.h"
#if defined(__ANDROID__)
#include "capstone/capstone.h"
#endif
#if defined(__i386__) || defined(__x86_64__)
#define MAX_INSTR_SZ 16
#elif defined(__arm__) || defined(__powerpc__) || defined(__powerpc64__)
#define MAX_INSTR_SZ 4
#elif defined(__aarch64__)
#define MAX_INSTR_SZ 8
#elif defined(__mips__) || defined(__mips64__)
#define MAX_INSTR_SZ 8
#elif defined(__riscv)
#define MAX_INSTR_SZ 4
#endif
#if defined(__i386__) || defined(__x86_64__)
struct user_regs_32 {
uint32_t ebx;
uint32_t ecx;
uint32_t edx;
uint32_t esi;
uint32_t edi;
uint32_t ebp;
uint32_t eax;
uint16_t ds, __ds;
uint16_t es, __es;
uint16_t fs, __fs;
uint16_t gs, __gs;
uint32_t orig_eax;
uint32_t eip;
uint16_t cs, __cs;
uint32_t eflags;
uint32_t esp;
uint16_t ss, __ss;
};
struct user_regs_64 {
uint64_t r15;
uint64_t r14;
uint64_t r13;
uint64_t r12;
uint64_t bp;
uint64_t bx;
uint64_t r11;
uint64_t r10;
uint64_t r9;
uint64_t r8;
uint64_t ax;
uint64_t cx;
uint64_t dx;
uint64_t si;
uint64_t di;
uint64_t orig_ax;
uint64_t ip;
uint64_t cs;
uint64_t flags;
uint64_t sp;
uint64_t ss;
uint64_t fs_base;
uint64_t gs_base;
uint64_t ds;
uint64_t es;
uint64_t fs;
uint64_t gs;
};
union user_regs_t {
struct user_regs_32 regs32;
struct user_regs_64 regs64;
};
#endif /* defined(__i386__) || defined(__x86_64__) */
#if defined(__arm__) || defined(__aarch64__)
struct user_regs_32 {
uint32_t r0;
uint32_t r1;
uint32_t r2;
uint32_t r3;
uint32_t r4;
uint32_t r5;
uint32_t r6;
uint32_t r7;
uint32_t r8;
uint32_t r9;
uint32_t r10;
uint32_t fp;
uint32_t ip;
uint32_t sp;
uint32_t lr;
uint32_t pc;
uint32_t cpsr;
uint32_t ORIG_r0;
};
struct user_regs_64 {
uint64_t regs[31];
uint64_t sp;
uint64_t pc;
uint64_t pstate;
};
union user_regs_t {
struct user_regs_32 regs32;
struct user_regs_64 regs64;
};
#endif /* defined(__arm__) || defined(__aarch64__) */
#if defined(__powerpc64__) || defined(__powerpc__)
struct user_regs_32 {
uint32_t gpr[32];
uint32_t nip;
uint32_t msr;
uint32_t orig_gpr3;
uint32_t ctr;
uint32_t link;
uint32_t xer;
uint32_t ccr;
uint32_t mq;
uint32_t trap;
uint32_t dar;
uint32_t dsisr;
uint32_t result;
/*
* elf.h's ELF_NGREG says it's 48 registers, so kernel fills it in
* with some zeros
*/
uint32_t zero0;
uint32_t zero1;
uint32_t zero2;
uint32_t zero3;
};
struct user_regs_64 {
uint64_t gpr[32];
uint64_t nip;
uint64_t msr;
uint64_t orig_gpr3;
uint64_t ctr;
uint64_t link;
uint64_t xer;
uint64_t ccr;
uint64_t softe;
uint64_t trap;
uint64_t dar;
uint64_t dsisr;
uint64_t result;
/*
* elf.h's ELF_NGREG says it's 48 registers, so kernel fills it in
* with some zeros
*/
uint64_t zero0;
uint64_t zero1;
uint64_t zero2;
uint64_t zero3;
};
union user_regs_t {
struct user_regs_32 regs32;
struct user_regs_64 regs64;
};
#endif /* defined(__powerpc64__) || defined(__powerpc__) */
#if defined(__mips__) || defined(__mips64__)
struct user_regs_64 {
uint64_t regs[32];
uint64_t lo;
uint64_t hi;
uint64_t cp0_epc;
uint64_t cp0_badvaddr;
uint64_t cp0_status;
uint64_t cp0_cause;
};
/*
* Despite what mips linux kernel headers/source code says, mips32 uses the same register laytout as
* mips64 only with GETREGS. With GETREGSET(NT_PRSTATUS) the structure size is 180 bytes
* (ELF_NGREG=45 * sizeof(uint32_t)=4 = 180). It also uses 24-byte padding for some,
* not-entierely-clear, reasons. The structure itself is not defined in the kernel, but only through
* how mips_dump_regs32() saves those registers via via MIPS32_EF_* defines.
*/
struct user_regs_32 {
uint32_t pad0[6];
uint32_t regs[32];
uint32_t lo;
uint32_t hi;
uint32_t cp0_epc;
uint32_t cp0_badvaddr;
uint32_t cp0_status;
uint32_t cp0_cause;
uint32_t unused0;
};
union user_regs_t {
struct user_regs_32 regs32;
struct user_regs_64 regs64;
};
#endif /* defined(__mips__) || defined(__mips64__) */
#if defined(__riscv)
struct user_regs_64 {
uint64_t epc;
uint64_t ra;
uint64_t sp;
uint64_t gp;
uint64_t tp;
uint64_t t0;
uint64_t t1;
uint64_t t2;
uint64_t s0;
uint64_t s1;
uint64_t a0;
uint64_t a1;
uint64_t a2;
uint64_t a3;
uint64_t a4;
uint64_t a5;
uint64_t a6;
uint64_t a7;
uint64_t s2;
uint64_t s3;
uint64_t s4;
uint64_t s5;
uint64_t s6;
uint64_t s7;
uint64_t s8;
uint64_t s9;
uint64_t s10;
uint64_t s11;
uint64_t t3;
uint64_t t4;
uint64_t t5;
uint64_t t6;
uint64_t status;
uint64_t badaddr;
uint64_t cause;
uint64_t orig_a0;
};
struct user_regs_32 {
uint32_t epc;
uint32_t ra;
uint32_t sp;
uint32_t gp;
uint32_t tp;
uint32_t t0;
uint32_t t1;
uint32_t t2;
uint32_t s0;
uint32_t s1;
uint32_t a0;
uint32_t a1;
uint32_t a2;
uint32_t a3;
uint32_t a4;
uint32_t a5;
uint32_t a6;
uint32_t a7;
uint32_t s2;
uint32_t s3;
uint32_t s4;
uint32_t s5;
uint32_t s6;
uint32_t s7;
uint32_t s8;
uint32_t s9;
uint32_t s10;
uint32_t s11;
uint32_t t3;
uint32_t t4;
uint32_t t5;
uint32_t t6;
uint32_t status;
uint32_t badaddr;
uint32_t cause;
uint32_t orig_a0;
};
union user_regs_t {
struct user_regs_32 regs32;
struct user_regs_64 regs64;
};
#endif /* defined(__riscv) */
#if defined(__clang__)
_Pragma("clang diagnostic push");
_Pragma("clang diagnostic ignored \"-Woverride-init\"");
#endif
static struct {
const char* descr;
bool important;
} arch_sigs[_NSIG + 1] = {
[0 ...(_NSIG)].important = false,
[0 ...(_NSIG)].descr = "UNKNOWN",
[SIGTRAP].important = false,
[SIGTRAP].descr = "SIGTRAP",
[SIGILL].important = true,
[SIGILL].descr = "SIGILL",
[SIGFPE].important = true,
[SIGFPE].descr = "SIGFPE",
[SIGSEGV].important = true,
[SIGSEGV].descr = "SIGSEGV",
[SIGBUS].important = true,
[SIGBUS].descr = "SIGBUS",
[SIGABRT].important = true,
[SIGABRT].descr = "SIGABRT",
/* Is affected from tmoutVTALRM flag */
[SIGVTALRM].important = false,
[SIGVTALRM].descr = "SIGVTALRM-TMOUT",
/* seccomp-bpf kill */
[SIGSYS].important = true,
[SIGSYS].descr = "SIGSYS",
};
#if defined(__clang__)
_Pragma("clang diagnostic pop");
#endif
#ifndef SI_FROMUSER
#define SI_FROMUSER(siptr) ((siptr)->si_code <= 0)
#endif /* SI_FROMUSER */
static size_t arch_getProcMem(pid_t pid, uint8_t* buf, size_t len, uint64_t pc) {
/*
* Let's try process_vm_readv first
*/
const struct iovec local_iov = {
.iov_base = buf,
.iov_len = len,
};
const struct iovec remote_iov = {
.iov_base = (void*)(uintptr_t)pc,
.iov_len = len,
};
if (process_vm_readv(pid, &local_iov, 1, &remote_iov, 1, 0) == (ssize_t)len) {
return len;
}
/* Debug if failed since it shouldn't happen very often */
PLOG_D("process_vm_readv() failed");
/*
* Ok, let's do it via ptrace() then.
* len must be aligned to the sizeof(long)
*/
int cnt = len / sizeof(long);
size_t memsz = 0;
for (int x = 0; x < cnt; x++) {
uint8_t* addr = (uint8_t*)(uintptr_t)pc + (int)(x * sizeof(long));
long ret = ptrace(PTRACE_PEEKDATA, pid, addr, NULL);
if (errno != 0) {
PLOG_W("Couldn't PT_READ_D on pid %d, addr: %p", pid, addr);
break;
}
memsz += sizeof(long);
memcpy(&buf[x * sizeof(long)], &ret, sizeof(long));
}
return memsz;
}
static size_t arch_getPC(pid_t pid, uint64_t* pc, uint64_t* status_reg HF_ATTR_UNUSED) {
union user_regs_t regs;
const struct iovec pt_iov = {
.iov_base = ®s,
.iov_len = sizeof(regs),
};
if (ptrace(PTRACE_GETREGSET, pid, NT_PRSTATUS, &pt_iov) == -1L) {
PLOG_D("ptrace(PTRACE_GETREGSET) failed");
return 0;
}
#if defined(__i386__) || defined(__x86_64__)
/* 32-bit */
if (pt_iov.iov_len == sizeof(struct user_regs_32)) {
*pc = regs.regs32.eip;
*status_reg = regs.regs32.eflags;
return pt_iov.iov_len;
}
/* 64-bit */
if (pt_iov.iov_len == sizeof(struct user_regs_64)) {
*pc = regs.regs64.ip;
*status_reg = regs.regs64.flags;
return pt_iov.iov_len;
}
LOG_W("Unknown registers structure size: '%zd'", pt_iov.iov_len);
return 0;
#endif /* defined(__i386__) || defined(__x86_64__) */
#if defined(__arm__) || defined(__aarch64__)
/* 32-bit */
if (pt_iov.iov_len == sizeof(struct user_regs_32)) {
*pc = regs.regs32.pc;
*status_reg = regs.regs32.cpsr;
return pt_iov.iov_len;
}
/* 64-bit */
if (pt_iov.iov_len == sizeof(struct user_regs_64)) {
*pc = regs.regs64.pc;
*status_reg = regs.regs64.pstate;
return pt_iov.iov_len;
}
LOG_W("Unknown registers structure size: '%zd'", pt_iov.iov_len);
return 0;
#endif /* defined(__arm__) || defined(__aarch64__) */
#if defined(__powerpc64__) || defined(__powerpc__)
/* 32-bit */
if (pt_iov.iov_len == sizeof(struct user_regs_32)) {
*pc = regs.regs32.nip;
return pt_iov.iov_len;
}
/* 64-bit */
if (pt_iov.iov_len == sizeof(struct user_regs_64)) {
*pc = regs.regs64.nip;
return pt_iov.iov_len;
}
LOG_W("Unknown registers structure size: '%zd'", pt_iov.iov_len);
return 0;
#endif /* defined(__powerpc64__) || defined(__powerpc__) */
#if defined(__mips__) || defined(__mips64__)
if (pt_iov.iov_len == sizeof(struct user_regs_64)) {
*pc = regs.regs64.cp0_epc;
return pt_iov.iov_len;
}
if (pt_iov.iov_len == sizeof(struct user_regs_32)) {
*pc = regs.regs32.cp0_epc;
return pt_iov.iov_len;
}
LOG_W("Unknown registers structure size: '%zd'", pt_iov.iov_len);
return 0;
#endif /* defined(__mips__) || defined(__mips64__) */
#if defined(__riscv)
if (pt_iov.iov_len == sizeof(struct user_regs_64)) {
*pc = regs.regs64.epc;
return pt_iov.iov_len;
}
if (pt_iov.iov_len == sizeof(struct user_regs_32)) {
*pc = regs.regs32.epc;
return pt_iov.iov_len;
}
LOG_W("Unknown registers structure size: '%zd'", pt_iov.iov_len);
return 0;
#endif /* defined(__riscv) */
LOG_D("Unknown/unsupported CPU architecture");
return 0;
}
static void arch_getInstrStr(pid_t pid, uint64_t pc, uint64_t status_reg HF_ATTR_UNUSED,
size_t pcRegSz HF_ATTR_UNUSED, char* instr) {
/*
* We need a value aligned to 8
* which is sizeof(long) on 64bit CPU archs (on most of them, I hope;)
*/
uint8_t buf[MAX_INSTR_SZ];
size_t memsz;
snprintf(instr, _HF_INSTR_SZ, "%s", "[UNKNOWN]");
if ((memsz = arch_getProcMem(pid, buf, sizeof(buf), pc)) == 0) {
snprintf(instr, _HF_INSTR_SZ, "%s", "[NOT_MMAPED]");
return;
}
#if !defined(__ANDROID__)
#if !defined(_HF_LINUX_NO_BFD)
arch_bfdDisasm(pid, buf, memsz, instr);
#endif /* !defined(_HF_LINUX_NO_BFD) */
#else /* !defined(__ANDROID__) */
cs_arch arch;
cs_mode mode;
#if defined(__arm__) || defined(__aarch64__)
arch = (pcRegSz == sizeof(struct user_regs_64)) ? CS_ARCH_ARM64 : CS_ARCH_ARM;
if (arch == CS_ARCH_ARM) {
mode = (status_reg & 0x20) ? CS_MODE_THUMB : CS_MODE_ARM;
} else {
mode = CS_MODE_ARM;
}
#elif defined(__i386__) || defined(__x86_64__)
arch = CS_ARCH_X86;
mode = (pcRegSz == sizeof(struct user_regs_64)) ? CS_MODE_64 : CS_MODE_32;
#else
LOG_E("Unknown/Unsupported Android CPU architecture");
#endif
csh handle;
cs_err err = cs_open(arch, mode, &handle);
if (err != CS_ERR_OK) {
LOG_W("Capstone initialization failed: '%s'", cs_strerror(err));
return;
}
cs_insn* insn;
size_t count = cs_disasm(handle, buf, sizeof(buf), pc, 0, &insn);
if (count < 1) {
LOG_W("Couldn't disassemble the assembler instructions' stream: '%s'",
cs_strerror(cs_errno(handle)));
cs_close(&handle);
return;
}
snprintf(instr, _HF_INSTR_SZ, "%s %s", insn[0].mnemonic, insn[0].op_str);
cs_free(insn, count);
cs_close(&handle);
#endif /* defined(__ANDROID__) */
for (int x = 0; instr[x] && x < _HF_INSTR_SZ; x++) {
if (instr[x] == '/' || instr[x] == '\\' || isspace(instr[x]) || !isprint(instr[x])) {
instr[x] = '_';
}
}
return;
}
static void arch_traceAnalyzeData(run_t* run, pid_t pid) {
funcs_t* funcs = util_Calloc(_HF_MAX_FUNCS * sizeof(funcs_t));
defer {
free(funcs);
};
uint64_t pc = 0;
uint64_t status_reg = 0;
size_t pcRegSz = arch_getPC(pid, &pc, &status_reg);
if (!pcRegSz) {
LOG_W("ptrace arch_getPC failed");
return;
}
uint64_t crashAddr = 0;
char description[HF_STR_LEN] = {};
size_t funcCnt = sanitizers_parseReport(run, pid, funcs, &pc, &crashAddr, description);
if (funcCnt <= 0) {
funcCnt = arch_unwindStack(pid, funcs);
#if !defined(__ANDROID__)
#if !defined(_HF_LINUX_NO_BFD)
arch_bfdResolveSyms(pid, funcs, funcCnt);
#endif /* !defined(_HF_LINUX_NO_BFD) */
#endif /* !defined(__ANDROID__) */
}
#if !defined(__ANDROID__)
#if !defined(_HF_LINUX_NO_BFD)
arch_bfdDemangle(funcs, funcCnt);
#endif /* !defined(_HF_LINUX_NO_BFD) */
#endif /* !defined(__ANDROID__) */
/*
* Calculate backtrace callstack hash signature
*/
run->backtrace = sanitizers_hashCallstack(run, funcs, funcCnt, false);
}
static void arch_traceSaveData(run_t* run, pid_t pid) {
char instr[_HF_INSTR_SZ] = "\x00";
siginfo_t si;
memset(&si, '\0', sizeof(si));
if (ptrace(PTRACE_GETSIGINFO, pid, 0, &si) == -1) {
PLOG_W("Couldn't get siginfo for pid %d", pid);
}
uint64_t crashAddr = (uint64_t)(uintptr_t)si.si_addr;
/* User-induced signals don't set si.si_addr */
if (SI_FROMUSER(&si)) {
crashAddr = 0UL;
}
int open_flags = O_CREAT | O_EXCL | O_WRONLY | O_CLOEXEC;
uint64_t pc = 0;
uint64_t status_reg = 0;
size_t pcRegSz = arch_getPC(pid, &pc, &status_reg);
if (!pcRegSz) {
LOG_W("ptrace arch_getPC failed");
return;
}
/*
* Unwind and resolve symbols
*/
funcs_t* funcs = util_Calloc(_HF_MAX_FUNCS * sizeof(funcs_t));
defer {
free(funcs);
};
char description[HF_STR_LEN] = {};
size_t funcCnt = sanitizers_parseReport(run, pid, funcs, &pc, &crashAddr, description);
if (funcCnt == 0) {
funcCnt = arch_unwindStack(pid, funcs);
#if !defined(__ANDROID__)
#if !defined(_HF_LINUX_NO_BFD)
arch_bfdResolveSyms(pid, funcs, funcCnt);
#endif /* !defined(_HF_LINUX_NO_BFD) */
#endif /* !defined(__ANDROID__) */
}
#if !defined(__ANDROID__)
#if !defined(_HF_LINUX_NO_BFD)
arch_bfdDemangle(funcs, funcCnt);
#endif /* !defined(_HF_LINUX_NO_BFD) */
#endif /* !defined(__ANDROID__) */
arch_getInstrStr(pid, pc, status_reg, pcRegSz, instr);
LOG_D("Pid: %d, signo: %d, errno: %d, code: %d, addr: %p, pc: %" PRIx64 ", crashAddr: %" PRIx64
" instr: '%s'",
pid, si.si_signo, si.si_errno, si.si_code, si.si_addr, pc, crashAddr, instr);
if (!SI_FROMUSER(&si) && pc &&
crashAddr < (uint64_t)(uintptr_t)run->global->arch_linux.ignoreAddr) {
LOG_I("Input is interesting (%s), but the si.si_addr is %p (below %p), skipping",
util_sigName(si.si_signo), si.si_addr, run->global->arch_linux.ignoreAddr);
return;
}
/*
* Temp local copy of previous backtrace value in case worker hit crashes into multiple
* tids for same target main thread. Will be 0 for first crash against target.
*/
uint64_t oldBacktrace = run->backtrace;
/* Local copy since flag is overridden for some crashes */
bool saveUnique = run->global->io.saveUnique;
/*
* Calculate backtrace callstack hash signature
*/
run->backtrace = sanitizers_hashCallstack(run, funcs, funcCnt, saveUnique);
/*
* If unique flag is set and single frame crash, disable uniqueness for this crash
* to always save (timestamp will be added to the filename)
*/
if (saveUnique && (funcCnt == 0)) {
saveUnique = false;
}
/*
* If worker crashFileName member is set, it means that a tid has already crashed
* from target main thread.
*/
if (run->crashFileName[0] != '\0') {
LOG_D("Multiple crashes detected from worker against attached tids group");
/*
* If stackhashes match, don't re-analyze. This will avoid duplicates
* and prevent verifier from running multiple passes. Depth of check is
* always 1 (last backtrace saved only per target iteration).
*/
if (oldBacktrace == run->backtrace) {
return;
}
}
/* Increase global crashes counter */
ATOMIC_POST_INC(run->global->cnts.crashesCnt);
/*
* Check if backtrace contains allowlisted symbol. Whitelist overrides
* both stackhash and symbol blocklist. Crash is always kept regardless
* of the status of uniqueness flag.
*/
if (run->global->arch_linux.symsWl) {
char* wlSymbol = arch_btContainsSymbol(
run->global->arch_linux.symsWlCnt, run->global->arch_linux.symsWl, funcCnt, funcs);
if (wlSymbol != NULL) {
saveUnique = false;
LOG_D("Whitelisted symbol '%s' found, skipping blocklist checks", wlSymbol);
}
} else {
/*
* Check if stackhash is blocklisted
*/
if (run->global->feedback.blocklist &&
(fastArray64Search(run->global->feedback.blocklist, run->global->feedback.blocklistCnt,
run->backtrace) != -1)) {
LOG_I("Blacklisted stack hash '%" PRIx64 "', skipping", run->backtrace);
ATOMIC_POST_INC(run->global->cnts.blCrashesCnt);
return;
}
/*
* Check if backtrace contains blocklisted symbol
*/
char* blSymbol = arch_btContainsSymbol(
run->global->arch_linux.symsBlCnt, run->global->arch_linux.symsBl, funcCnt, funcs);
if (blSymbol != NULL) {
LOG_I("Blacklisted symbol '%s' found, skipping", blSymbol);
ATOMIC_POST_INC(run->global->cnts.blCrashesCnt);
return;
}
}
/* If non-blocklisted crash detected, zero set two MSB */
ATOMIC_POST_ADD(run->global->cfg.dynFileIterExpire, _HF_DYNFILE_SUB_MASK);
/* Those addresses will be random, so depend on stack-traces for uniqueness */
if (!run->global->arch_linux.disableRandomization) {
pc = 0UL;
crashAddr = 0UL;
}
/* crashAddr (si.si_addr) never makes sense for SIGABRT */
if (si.si_signo == SIGABRT) {
crashAddr = 0UL;
}
/* If dry run mode, copy file with same name into workspace */
if (run->global->mutate.mutationsPerRun == 0U && run->global->cfg.useVerifier) {
snprintf(run->crashFileName, sizeof(run->crashFileName), "%s/%s", run->global->io.crashDir,
run->dynfile->path);
} else if (saveUnique) {
snprintf(run->crashFileName, sizeof(run->crashFileName),
"%s/%s.PC.%" PRIx64 ".STACK.%" PRIx64 ".CODE.%d.ADDR.%" PRIx64 ".INSTR.%s.%s",
run->global->io.crashDir, util_sigName(si.si_signo), pc, run->backtrace, si.si_code,
crashAddr, instr, run->global->io.fileExtn);
} else {
char localtmstr[HF_STR_LEN];
util_getLocalTime("%F.%H:%M:%S", localtmstr, sizeof(localtmstr), time(NULL));
snprintf(run->crashFileName, sizeof(run->crashFileName),
"%s/%s.PC.%" PRIx64 ".STACK.%" PRIx64 ".CODE.%d.ADDR.%" PRIx64 ".INSTR.%s.%s.%d.%s",
run->global->io.crashDir, util_sigName(si.si_signo), pc, run->backtrace, si.si_code,
crashAddr, instr, localtmstr, pid, run->global->io.fileExtn);
}
/* Target crashed (no duplicate detection yet) */
if (run->global->socketFuzzer.enabled) {
LOG_D("SocketFuzzer: trace: Crash Identified");
}
if (files_exists(run->crashFileName)) {
if (run->global->io.saveSmaller) {
/*
* If the new run produces a smaller file than exists already, we
* will replace it.
*
* If this is the second test case, we save the first with .orig
* suffix before overwriting.
*/
struct stat st;
char origFile[PATH_MAX];
if (stat(run->crashFileName, &st) == -1) {
LOG_W("Couldn't stat() the '%s' file", run->crashFileName);
} else if (st.st_size <= (off_t)run->dynfile->size) {
LOG_I("Crash (dup): '%s' exists and is smaller, skipping", run->crashFileName);
/* Clear filename so that verifier can understand we hit a duplicate */
memset(run->crashFileName, 0, sizeof(run->crashFileName));
return;
} else {
/* we have a new champion */
LOG_I("Crash: overwriting '%s' (old %zu bytes, new %zu bytes)", run->crashFileName,
(size_t)st.st_size, (size_t)run->dynfile->size);
}
snprintf(origFile, sizeof(origFile), "%s.orig", run->crashFileName);
if (!files_exists(origFile)) {
rename(run->crashFileName, origFile);
} else {
/* allow overwrite */
open_flags = O_CREAT | O_WRONLY | O_CLOEXEC;
}
} else {
LOG_I("Crash (dup): '%s' already exists, skipping", run->crashFileName);
/* Clear filename so that verifier can understand we hit a duplicate */
memset(run->crashFileName, 0, sizeof(run->crashFileName));
return;
}
}
if (!files_writeBufToFile(
run->crashFileName, run->dynfile->data, run->dynfile->size, open_flags)) {
LOG_E("Couldn't write to '%s'", run->crashFileName);
return;
}
/* Unique new crash, notify fuzzer */
if (run->global->socketFuzzer.enabled) {
LOG_D("SocketFuzzer: trace: New Uniqu Crash");
fuzz_notifySocketFuzzerCrash(run);
}
LOG_I("Crash: saved as '%s'", run->crashFileName);
ATOMIC_POST_INC(run->global->cnts.uniqueCrashesCnt);
/* If unique crash found, reset dynFile counter */
ATOMIC_CLEAR(run->global->cfg.dynFileIterExpire);
report_appendReport(pid, run, funcs, funcCnt, pc, crashAddr, si.si_signo, instr, description);
}
#define __WEVENT(status) ((status & 0xFF0000) >> 16)
static void arch_traceEvent(int status, pid_t pid) {
LOG_D("PID: %d, Ptrace event: %d", pid, __WEVENT(status));
switch (__WEVENT(status)) {
case PTRACE_EVENT_EXIT: {
unsigned long event_msg;
if (ptrace(PTRACE_GETEVENTMSG, pid, NULL, &event_msg) == -1) {
PLOG_E("ptrace(PTRACE_GETEVENTMSG,%d) failed", pid);
return;
}
if (WIFEXITED(event_msg)) {
LOG_D("PID: %d exited with exit_code: %lu", pid, (unsigned long)WEXITSTATUS(event_msg));
} else if (WIFSIGNALED(event_msg)) {
LOG_D("PID: %d terminated with signal: %lu", pid, (unsigned long)WTERMSIG(event_msg));
} else {
LOG_D("PID: %d exited with unknown status: %lu (%s)", pid, event_msg,
subproc_StatusToStr(event_msg));
}
} break;
default:
break;
}
ptrace(PTRACE_CONT, pid, 0, 0);
}
void arch_traceAnalyze(run_t* run, int status, pid_t pid) {
/*
* It's a ptrace event, deal with it elsewhere
*/
if (WIFSTOPPED(status) && __WEVENT(status)) {
return arch_traceEvent(status, pid);
}
if (WIFSTOPPED(status)) {
/*
* If it's an interesting signal, save the testcase
*/
if (arch_sigs[WSTOPSIG(status)].important) {
/*
* If fuzzer worker is from core fuzzing process run full
* analysis. Otherwise just unwind and get stack hash signature.
*/
if (run->mainWorker) {
arch_traceSaveData(run, pid);
} else {
arch_traceAnalyzeData(run, pid);
}
}
/* Do not deliver SIGSTOP, as we don't support PTRACE_LISTEN anyway */
int sig = (WSTOPSIG(status) != SIGSTOP) ? WSTOPSIG(status) : 0;
ptrace(PTRACE_CONT, pid, 0, sig);
return;
}
/*
* Resumed by delivery of SIGCONT
*/
if (WIFCONTINUED(status)) {
return;
}
/*
* Process exited
*/
if (WIFEXITED(status)) {
return;
}
if (WIFSIGNALED(status)) {
return;
}
abort(); /* NOTREACHED */
}
static bool arch_listThreads(int tasks[], size_t thrSz, int pid) {
char path[512];
snprintf(path, sizeof(path), "/proc/%d/task", pid);
/* An optimization, the number of threads is st.st_nlink - 2 (. and ..) */
struct stat st;
if (stat(path, &st) != -1) {
if (st.st_nlink == 3) {
tasks[0] = pid;
tasks[1] = 0;
return true;
}
}
size_t count = 0;
DIR* dir = opendir(path);
if (!dir) {
PLOG_E("Couldn't open dir '%s'", path);
return false;
}
defer {
closedir(dir);
};
for (;;) {
errno = 0;
const struct dirent* res = readdir(dir);
if (res == NULL && errno != 0) {
PLOG_E("Couldn't read contents of '%s'", path);
return false;
}
if (res == NULL) {
break;
}
pid_t pid = (pid_t)strtol(res->d_name, (char**)NULL, 10);
if (pid == 0) {
LOG_D("The following dir entry couldn't be converted to pid_t '%s'", res->d_name);
continue;
}
tasks[count++] = pid;
LOG_D("Added pid '%d' from '%s/%s'", pid, path, res->d_name);
if (count >= thrSz) {
break;
}
}
PLOG_D("Total number of threads in pid '%d': '%zd'", pid, count);