freebsd-skq/usr.bin/truss/syscalls.c
John Baldwin c915ff0349 Expand the decoding of kevent structures.
- Print the ident value as decimal instead of hexadecimal for filter types
  that use "small" values such as file descriptors and PIDs.
- Decode NOTE_* flags in the fflags field of kevents for several system
  filter types.
2015-08-19 01:44:56 +00:00

1587 lines
47 KiB
C

/*
* Copyright 1997 Sean Eric Fagan
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Sean Eric Fagan
* 4. Neither the name of the author may be used to endorse or promote
* products derived from this software without specific prior written
* permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#ifndef lint
static const char rcsid[] =
"$FreeBSD$";
#endif /* not lint */
/*
* This file has routines used to print out system calls and their
* arguments.
*/
#include <sys/types.h>
#include <sys/mman.h>
#include <sys/procctl.h>
#include <sys/ptrace.h>
#include <sys/socket.h>
#include <sys/time.h>
#include <sys/un.h>
#include <sys/wait.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <sys/ioccom.h>
#include <machine/atomic.h>
#include <errno.h>
#include <sys/umtx.h>
#include <sys/event.h>
#include <sys/stat.h>
#include <sys/resource.h>
#include <machine/sysarch.h>
#include <ctype.h>
#include <err.h>
#include <fcntl.h>
#include <poll.h>
#include <signal.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <vis.h>
#include "truss.h"
#include "extern.h"
#include "syscall.h"
/* 64-bit alignment on 32-bit platforms. */
#ifdef __powerpc__
#define QUAD_ALIGN 1
#else
#define QUAD_ALIGN 0
#endif
/* Number of slots needed for a 64-bit argument. */
#ifdef __LP64__
#define QUAD_SLOTS 1
#else
#define QUAD_SLOTS 2
#endif
/*
* This should probably be in its own file, sorted alphabetically.
*/
static struct syscall syscalls[] = {
{ .name = "fcntl", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Fcntl, 1 }, { Fcntlflag, 2 } } },
{ .name = "fork", .ret_type = 1, .nargs = 0 },
{ .name = "vfork", .ret_type = 1, .nargs = 0 },
{ .name = "rfork", .ret_type = 1, .nargs = 1,
.args = { { Rforkflags, 0 } } },
{ .name = "getegid", .ret_type = 1, .nargs = 0 },
{ .name = "geteuid", .ret_type = 1, .nargs = 0 },
{ .name = "linux_readlink", .ret_type = 1, .nargs = 3,
.args = { { Name, 0 }, { Name | OUT, 1 }, { Int, 2 } } },
{ .name = "linux_socketcall", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { LinuxSockArgs, 1 } } },
{ .name = "getgid", .ret_type = 1, .nargs = 0 },
{ .name = "getpid", .ret_type = 1, .nargs = 0 },
{ .name = "getpgid", .ret_type = 1, .nargs = 1,
.args = { { Int, 0 } } },
{ .name = "getpgrp", .ret_type = 1, .nargs = 0 },
{ .name = "getppid", .ret_type = 1, .nargs = 0 },
{ .name = "getsid", .ret_type = 1, .nargs = 1,
.args = { { Int, 0 } } },
{ .name = "getuid", .ret_type = 1, .nargs = 0 },
{ .name = "issetugid", .ret_type = 1, .nargs = 0 },
{ .name = "readlink", .ret_type = 1, .nargs = 3,
.args = { { Name, 0 }, { Readlinkres | OUT, 1 }, { Int, 2 } } },
{ .name = "readlinkat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Name, 1 }, { Readlinkres | OUT, 2 },
{ Int, 3 } } },
{ .name = "lseek", .ret_type = 2, .nargs = 3,
.args = { { Int, 0 }, { Quad, 1 + QUAD_ALIGN },
{ Whence, 1 + QUAD_SLOTS + QUAD_ALIGN } } },
{ .name = "linux_lseek", .ret_type = 2, .nargs = 3,
.args = { { Int, 0 }, { Int, 1 }, { Whence, 2 } } },
{ .name = "mmap", .ret_type = 2, .nargs = 6,
.args = { { Ptr, 0 }, { Int, 1 }, { Mprot, 2 }, { Mmapflags, 3 },
{ Int, 4 }, { Quad, 5 + QUAD_ALIGN } } },
{ .name = "linux_mkdir", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Int, 1 } } },
{ .name = "mprotect", .ret_type = 1, .nargs = 3,
.args = { { Ptr, 0 }, { Int, 1 }, { Mprot, 2 } } },
{ .name = "open", .ret_type = 1, .nargs = 3,
.args = { { Name | IN, 0 }, { Open, 1 }, { Octal, 2 } } },
{ .name = "openat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Name | IN, 1 }, { Open, 2 },
{ Octal, 3 } } },
{ .name = "mkdir", .ret_type = 1, .nargs = 2,
.args = { { Name, 0 }, { Octal, 1 } } },
{ .name = "mkdirat", .ret_type = 1, .nargs = 3,
.args = { { Atfd, 0 }, { Name, 1 }, { Octal, 2 } } },
{ .name = "linux_open", .ret_type = 1, .nargs = 3,
.args = { { Name, 0 }, { Hex, 1 }, { Octal, 2 } } },
{ .name = "close", .ret_type = 1, .nargs = 1,
.args = { { Int, 0 } } },
{ .name = "link", .ret_type = 0, .nargs = 2,
.args = { { Name, 0 }, { Name, 1 } } },
{ .name = "linkat", .ret_type = 0, .nargs = 5,
.args = { { Atfd, 0 }, { Name, 1 }, { Atfd, 2 }, { Name, 3 },
{ Atflags, 4 } } },
{ .name = "unlink", .ret_type = 0, .nargs = 1,
.args = { { Name, 0 } } },
{ .name = "unlinkat", .ret_type = 0, .nargs = 3,
.args = { { Atfd, 0 }, { Name, 1 }, { Atflags, 2 } } },
{ .name = "chdir", .ret_type = 0, .nargs = 1,
.args = { { Name, 0 } } },
{ .name = "chroot", .ret_type = 0, .nargs = 1,
.args = { { Name, 0 } } },
{ .name = "mkfifo", .ret_type = 0, .nargs = 2,
.args = { { Name, 0 }, { Octal, 1 } } },
{ .name = "mkfifoat", .ret_type = 0, .nargs = 3,
.args = { { Atfd, 0 }, { Name, 1 }, { Octal, 2 } } },
{ .name = "mknod", .ret_type = 0, .nargs = 3,
.args = { { Name, 0 }, { Octal, 1 }, { Int, 2 } } },
{ .name = "mknodat", .ret_type = 0, .nargs = 4,
.args = { { Atfd, 0 }, { Name, 1 }, { Octal, 2 }, { Int, 3 } } },
{ .name = "chmod", .ret_type = 0, .nargs = 2,
.args = { { Name, 0 }, { Octal, 1 } } },
{ .name = "fchmod", .ret_type = 0, .nargs = 2,
.args = { { Int, 0 }, { Octal, 1 } } },
{ .name = "lchmod", .ret_type = 0, .nargs = 2,
.args = { { Name, 0 }, { Octal, 1 } } },
{ .name = "fchmodat", .ret_type = 0, .nargs = 4,
.args = { { Atfd, 0 }, { Name, 1 }, { Octal, 2 }, { Atflags, 3 } } },
{ .name = "chown", .ret_type = 0, .nargs = 3,
.args = { { Name, 0 }, { Int, 1 }, { Int, 2 } } },
{ .name = "fchown", .ret_type = 0, .nargs = 3,
.args = { { Int, 0 }, { Int, 1 }, { Int, 2 } } },
{ .name = "lchown", .ret_type = 0, .nargs = 3,
.args = { { Name, 0 }, { Int, 1 }, { Int, 2 } } },
{ .name = "fchownat", .ret_type = 0, .nargs = 5,
.args = { { Atfd, 0 }, { Name, 1 }, { Int, 2 }, { Int, 3 },
{ Atflags, 4 } } },
{ .name = "linux_stat64", .ret_type = 1, .nargs = 3,
.args = { { Name | IN, 0 }, { Ptr | OUT, 1 }, { Ptr | IN, 1 } } },
{ .name = "mount", .ret_type = 0, .nargs = 4,
.args = { { Name, 0 }, { Name, 1 }, { Int, 2 }, { Ptr, 3 } } },
{ .name = "umount", .ret_type = 0, .nargs = 2,
.args = { { Name, 0 }, { Int, 2 } } },
{ .name = "fstat", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Stat | OUT, 1 } } },
{ .name = "fstatat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Name | IN, 1 }, { Stat | OUT, 2 },
{ Atflags, 3 } } },
{ .name = "stat", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Stat | OUT, 1 } } },
{ .name = "lstat", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Stat | OUT, 1 } } },
{ .name = "linux_newstat", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Ptr | OUT, 1 } } },
{ .name = "linux_access", .ret_type = 1, .nargs = 2,
.args = { { Name, 0 }, { Accessmode, 1 } } },
{ .name = "linux_newfstat", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Ptr | OUT, 1 } } },
{ .name = "write", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { BinString | IN, 1 }, { Int, 2 } } },
{ .name = "ioctl", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Ioctl, 1 }, { Hex, 2 } } },
{ .name = "break", .ret_type = 1, .nargs = 1,
.args = { { Ptr, 0 } } },
{ .name = "exit", .ret_type = 0, .nargs = 1,
.args = { { Hex, 0 } } },
{ .name = "access", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Accessmode, 1 } } },
{ .name = "eaccess", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Accessmode, 1 } } },
{ .name = "faccessat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Name | IN, 1 }, { Accessmode, 2 },
{ Atflags, 3 } } },
{ .name = "sigaction", .ret_type = 1, .nargs = 3,
.args = { { Signal, 0 }, { Sigaction | IN, 1 },
{ Sigaction | OUT, 2 } } },
{ .name = "accept", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Sockaddr | OUT, 1 }, { Ptr | OUT, 2 } } },
{ .name = "bind", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Sockaddr | IN, 1 }, { Int, 2 } } },
{ .name = "bindat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Int, 1 }, { Sockaddr | IN, 2 },
{ Int, 3 } } },
{ .name = "connect", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Sockaddr | IN, 1 }, { Int, 2 } } },
{ .name = "connectat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Int, 1 }, { Sockaddr | IN, 2 },
{ Int, 3 } } },
{ .name = "getpeername", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Sockaddr | OUT, 1 }, { Ptr | OUT, 2 } } },
{ .name = "getsockname", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Sockaddr | OUT, 1 }, { Ptr | OUT, 2 } } },
{ .name = "recvfrom", .ret_type = 1, .nargs = 6,
.args = { { Int, 0 }, { BinString | OUT, 1 }, { Int, 2 }, { Hex, 3 },
{ Sockaddr | OUT, 4 }, { Ptr | OUT, 5 } } },
{ .name = "sendto", .ret_type = 1, .nargs = 6,
.args = { { Int, 0 }, { BinString | IN, 1 }, { Int, 2 }, { Hex, 3 },
{ Sockaddr | IN, 4 }, { Ptr | IN, 5 } } },
{ .name = "execve", .ret_type = 1, .nargs = 3,
.args = { { Name | IN, 0 }, { StringArray | IN, 1 },
{ StringArray | IN, 2 } } },
{ .name = "linux_execve", .ret_type = 1, .nargs = 3,
.args = { { Name | IN, 0 }, { StringArray | IN, 1 },
{ StringArray | IN, 2 } } },
{ .name = "kldload", .ret_type = 0, .nargs = 1,
.args = { { Name | IN, 0 } } },
{ .name = "kldunload", .ret_type = 0, .nargs = 1,
.args = { { Int, 0 } } },
{ .name = "kldfind", .ret_type = 0, .nargs = 1,
.args = { { Name | IN, 0 } } },
{ .name = "kldnext", .ret_type = 0, .nargs = 1,
.args = { { Int, 0 } } },
{ .name = "kldstat", .ret_type = 0, .nargs = 2,
.args = { { Int, 0 }, { Ptr, 1 } } },
{ .name = "kldfirstmod", .ret_type = 0, .nargs = 1,
.args = { { Int, 0 } } },
{ .name = "nanosleep", .ret_type = 0, .nargs = 1,
.args = { { Timespec, 0 } } },
{ .name = "select", .ret_type = 1, .nargs = 5,
.args = { { Int, 0 }, { Fd_set, 1 }, { Fd_set, 2 }, { Fd_set, 3 },
{ Timeval, 4 } } },
{ .name = "poll", .ret_type = 1, .nargs = 3,
.args = { { Pollfd, 0 }, { Int, 1 }, { Int, 2 } } },
{ .name = "gettimeofday", .ret_type = 1, .nargs = 2,
.args = { { Timeval | OUT, 0 }, { Ptr, 1 } } },
{ .name = "clock_gettime", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Timespec | OUT, 1 } } },
{ .name = "getitimer", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Itimerval | OUT, 2 } } },
{ .name = "setitimer", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { Itimerval, 1 }, { Itimerval | OUT, 2 } } },
{ .name = "kse_release", .ret_type = 0, .nargs = 1,
.args = { { Timespec, 0 } } },
{ .name = "kevent", .ret_type = 0, .nargs = 6,
.args = { { Int, 0 }, { Kevent, 1 }, { Int, 2 }, { Kevent | OUT, 3 },
{ Int, 4 }, { Timespec, 5 } } },
{ .name = "sigpending", .ret_type = 0, .nargs = 1,
.args = { { Sigset | OUT, 0 } } },
{ .name = "sigprocmask", .ret_type = 0, .nargs = 3,
.args = { { Sigprocmask, 0 }, { Sigset, 1 }, { Sigset | OUT, 2 } } },
{ .name = "sigqueue", .ret_type = 0, .nargs = 3,
.args = { { Int, 0 }, { Signal, 1 }, { LongHex, 2 } } },
{ .name = "sigreturn", .ret_type = 0, .nargs = 1,
.args = { { Ptr, 0 } } },
{ .name = "sigsuspend", .ret_type = 0, .nargs = 1,
.args = { { Sigset | IN, 0 } } },
{ .name = "sigtimedwait", .ret_type = 1, .nargs = 3,
.args = { { Sigset | IN, 0 }, { Ptr, 1 }, { Timespec | IN, 2 } } },
{ .name = "sigwait", .ret_type = 1, .nargs = 2,
.args = { { Sigset | IN, 0 }, { Ptr, 1 } } },
{ .name = "sigwaitinfo", .ret_type = 1, .nargs = 2,
.args = { { Sigset | IN, 0 }, { Ptr, 1 } } },
{ .name = "unmount", .ret_type = 1, .nargs = 2,
.args = { { Name, 0 }, { Int, 1 } } },
{ .name = "socket", .ret_type = 1, .nargs = 3,
.args = { { Sockdomain, 0 }, { Socktype, 1 }, { Int, 2 } } },
{ .name = "getrusage", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Rusage | OUT, 1 } } },
{ .name = "__getcwd", .ret_type = 1, .nargs = 2,
.args = { { Name | OUT, 0 }, { Int, 1 } } },
{ .name = "shutdown", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Shutdown, 1 } } },
{ .name = "getrlimit", .ret_type = 1, .nargs = 2,
.args = { { Resource, 0 }, { Rlimit | OUT, 1 } } },
{ .name = "setrlimit", .ret_type = 1, .nargs = 2,
.args = { { Resource, 0 }, { Rlimit | IN, 1 } } },
{ .name = "utimes", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Timeval2 | IN, 1 } } },
{ .name = "lutimes", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Timeval2 | IN, 1 } } },
{ .name = "futimes", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Timeval2 | IN, 1 } } },
{ .name = "futimesat", .ret_type = 1, .nargs = 3,
.args = { { Atfd, 0 }, { Name | IN, 1 }, { Timeval2 | IN, 2 } } },
{ .name = "futimens", .ret_type = 1, .nargs = 2,
.args = { { Int, 0 }, { Timespec2 | IN, 1 } } },
{ .name = "utimensat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Name | IN, 1 }, { Timespec2 | IN, 2 },
{ Atflags, 3 } } },
{ .name = "chflags", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Hex, 1 } } },
{ .name = "lchflags", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Hex, 1 } } },
{ .name = "pathconf", .ret_type = 1, .nargs = 2,
.args = { { Name | IN, 0 }, { Pathconf, 1 } } },
{ .name = "pipe", .ret_type = 1, .nargs = 1,
.args = { { Ptr, 0 } } },
{ .name = "pipe2", .ret_type = 1, .nargs = 2,
.args = { { Ptr, 0 }, { Open, 1 } } },
{ .name = "truncate", .ret_type = 1, .nargs = 3,
.args = { { Name | IN, 0 }, { Int | IN, 1 }, { Quad | IN, 2 } } },
{ .name = "ftruncate", .ret_type = 1, .nargs = 3,
.args = { { Int | IN, 0 }, { Int | IN, 1 }, { Quad | IN, 2 } } },
{ .name = "kill", .ret_type = 1, .nargs = 2,
.args = { { Int | IN, 0 }, { Signal | IN, 1 } } },
{ .name = "munmap", .ret_type = 1, .nargs = 2,
.args = { { Ptr, 0 }, { Int, 1 } } },
{ .name = "read", .ret_type = 1, .nargs = 3,
.args = { { Int, 0 }, { BinString | OUT, 1 }, { Int, 2 } } },
{ .name = "rename", .ret_type = 1, .nargs = 2,
.args = { { Name, 0 }, { Name, 1 } } },
{ .name = "renameat", .ret_type = 1, .nargs = 4,
.args = { { Atfd, 0 }, { Name, 1 }, { Atfd, 2 }, { Name, 3 } } },
{ .name = "symlink", .ret_type = 1, .nargs = 2,
.args = { { Name, 0 }, { Name, 1 } } },
{ .name = "symlinkat", .ret_type = 1, .nargs = 3,
.args = { { Name, 0 }, { Atfd, 1 }, { Name, 2 } } },
{ .name = "posix_openpt", .ret_type = 1, .nargs = 1,
.args = { { Open, 0 } } },
{ .name = "wait4", .ret_type = 1, .nargs = 4,
.args = { { Int, 0 }, { ExitStatus | OUT, 1 }, { Waitoptions, 2 },
{ Rusage | OUT, 3 } } },
{ .name = "wait6", .ret_type = 1, .nargs = 6,
.args = { { Idtype, 0 }, { Int, 1 }, { ExitStatus | OUT, 2 },
{ Waitoptions, 3 }, { Rusage | OUT, 4 }, { Ptr, 5 } } },
{ .name = "procctl", .ret_type = 1, .nargs = 4,
.args = { { Idtype, 0 }, { Int, 1 }, { Procctl, 2 }, { Ptr, 3 } } },
{ .name = "sysarch", .ret_type = 1, .nargs = 2,
.args = { { Sysarch, 0 }, { Ptr, 1 } } },
{ .name = "_umtx_op", .ret_type = 1, .nargs = 5,
.args = { { Ptr, 0 }, { Umtxop, 1 }, { LongHex, 2 }, { Ptr, 3 },
{ Ptr, 4 } } },
{ .name = "thr_kill", .ret_type = 0, .nargs = 2,
.args = { { Long, 0 }, { Signal, 1 } } },
{ .name = "thr_self", .ret_type = 0, .nargs = 1,
.args = { { Ptr, 0 } } },
{ .name = 0 },
};
/* Xlat idea taken from strace */
struct xlat {
int val;
const char *str;
};
#define X(a) { a, #a },
#define XEND { 0, NULL }
static struct xlat kevent_filters[] = {
X(EVFILT_READ) X(EVFILT_WRITE) X(EVFILT_AIO) X(EVFILT_VNODE)
X(EVFILT_PROC) X(EVFILT_SIGNAL) X(EVFILT_TIMER)
X(EVFILT_PROCDESC) X(EVFILT_FS) X(EVFILT_LIO) X(EVFILT_USER)
X(EVFILT_SENDFILE) XEND
};
static struct xlat kevent_flags[] = {
X(EV_ADD) X(EV_DELETE) X(EV_ENABLE) X(EV_DISABLE) X(EV_ONESHOT)
X(EV_CLEAR) X(EV_RECEIPT) X(EV_DISPATCH) X(EV_FORCEONESHOT)
X(EV_DROP) X(EV_FLAG1) X(EV_ERROR) X(EV_EOF) XEND
};
static struct xlat kevent_user_ffctrl[] = {
X(NOTE_FFNOP) X(NOTE_FFAND) X(NOTE_FFOR) X(NOTE_FFCOPY)
XEND
};
static struct xlat kevent_rdwr_fflags[] = {
X(NOTE_LOWAT) X(NOTE_FILE_POLL) XEND
};
static struct xlat kevent_vnode_fflags[] = {
X(NOTE_DELETE) X(NOTE_WRITE) X(NOTE_EXTEND) X(NOTE_ATTRIB)
X(NOTE_LINK) X(NOTE_RENAME) X(NOTE_REVOKE) XEND
};
static struct xlat kevent_proc_fflags[] = {
X(NOTE_EXIT) X(NOTE_FORK) X(NOTE_EXEC) X(NOTE_TRACK) X(NOTE_TRACKERR)
X(NOTE_CHILD) XEND
};
static struct xlat kevent_timer_fflags[] = {
X(NOTE_SECONDS) X(NOTE_MSECONDS) X(NOTE_USECONDS) X(NOTE_NSECONDS)
XEND
};
static struct xlat poll_flags[] = {
X(POLLSTANDARD) X(POLLIN) X(POLLPRI) X(POLLOUT) X(POLLERR)
X(POLLHUP) X(POLLNVAL) X(POLLRDNORM) X(POLLRDBAND)
X(POLLWRBAND) X(POLLINIGNEOF) XEND
};
static struct xlat mmap_flags[] = {
X(MAP_SHARED) X(MAP_PRIVATE) X(MAP_FIXED) X(MAP_RESERVED0020)
X(MAP_RESERVED0040) X(MAP_RESERVED0080) X(MAP_RESERVED0100)
X(MAP_HASSEMAPHORE) X(MAP_STACK) X(MAP_NOSYNC) X(MAP_ANON)
X(MAP_EXCL) X(MAP_NOCORE) X(MAP_PREFAULT_READ)
#ifdef MAP_32BIT
X(MAP_32BIT)
#endif
XEND
};
static struct xlat mprot_flags[] = {
X(PROT_NONE) X(PROT_READ) X(PROT_WRITE) X(PROT_EXEC) XEND
};
static struct xlat whence_arg[] = {
X(SEEK_SET) X(SEEK_CUR) X(SEEK_END) X(SEEK_DATA) X(SEEK_HOLE) XEND
};
static struct xlat sigaction_flags[] = {
X(SA_ONSTACK) X(SA_RESTART) X(SA_RESETHAND) X(SA_NOCLDSTOP)
X(SA_NODEFER) X(SA_NOCLDWAIT) X(SA_SIGINFO) XEND
};
static struct xlat fcntl_arg[] = {
X(F_DUPFD) X(F_GETFD) X(F_SETFD) X(F_GETFL) X(F_SETFL)
X(F_GETOWN) X(F_SETOWN) X(F_OGETLK) X(F_OSETLK) X(F_OSETLKW)
X(F_DUP2FD) X(F_GETLK) X(F_SETLK) X(F_SETLKW) X(F_SETLK_REMOTE)
X(F_READAHEAD) X(F_RDAHEAD) X(F_DUPFD_CLOEXEC) X(F_DUP2FD_CLOEXEC)
XEND
};
static struct xlat fcntlfd_arg[] = {
X(FD_CLOEXEC) XEND
};
static struct xlat fcntlfl_arg[] = {
X(O_APPEND) X(O_ASYNC) X(O_FSYNC) X(O_NONBLOCK) X(O_NOFOLLOW)
X(FRDAHEAD) X(O_DIRECT) XEND
};
static struct xlat sockdomain_arg[] = {
X(PF_UNSPEC) X(PF_LOCAL) X(PF_UNIX) X(PF_INET) X(PF_IMPLINK)
X(PF_PUP) X(PF_CHAOS) X(PF_NETBIOS) X(PF_ISO) X(PF_OSI)
X(PF_ECMA) X(PF_DATAKIT) X(PF_CCITT) X(PF_SNA) X(PF_DECnet)
X(PF_DLI) X(PF_LAT) X(PF_HYLINK) X(PF_APPLETALK) X(PF_ROUTE)
X(PF_LINK) X(PF_XTP) X(PF_COIP) X(PF_CNT) X(PF_SIP) X(PF_IPX)
X(PF_RTIP) X(PF_PIP) X(PF_ISDN) X(PF_KEY) X(PF_INET6)
X(PF_NATM) X(PF_ATM) X(PF_NETGRAPH) X(PF_SLOW) X(PF_SCLUSTER)
X(PF_ARP) X(PF_BLUETOOTH) X(PF_IEEE80211) X(PF_INET_SDP)
X(PF_INET6_SDP) XEND
};
static struct xlat socktype_arg[] = {
X(SOCK_STREAM) X(SOCK_DGRAM) X(SOCK_RAW) X(SOCK_RDM)
X(SOCK_SEQPACKET) XEND
};
static struct xlat open_flags[] = {
X(O_RDONLY) X(O_WRONLY) X(O_RDWR) X(O_ACCMODE) X(O_NONBLOCK)
X(O_APPEND) X(O_SHLOCK) X(O_EXLOCK) X(O_ASYNC) X(O_FSYNC)
X(O_NOFOLLOW) X(O_CREAT) X(O_TRUNC) X(O_EXCL) X(O_NOCTTY)
X(O_DIRECT) X(O_DIRECTORY) X(O_EXEC) X(O_TTY_INIT) X(O_CLOEXEC)
X(O_VERIFY) XEND
};
static struct xlat shutdown_arg[] = {
X(SHUT_RD) X(SHUT_WR) X(SHUT_RDWR) XEND
};
static struct xlat resource_arg[] = {
X(RLIMIT_CPU) X(RLIMIT_FSIZE) X(RLIMIT_DATA) X(RLIMIT_STACK)
X(RLIMIT_CORE) X(RLIMIT_RSS) X(RLIMIT_MEMLOCK) X(RLIMIT_NPROC)
X(RLIMIT_NOFILE) X(RLIMIT_SBSIZE) X(RLIMIT_VMEM) X(RLIMIT_NPTS)
X(RLIMIT_SWAP) X(RLIMIT_KQUEUES) XEND
};
static struct xlat pathconf_arg[] = {
X(_PC_LINK_MAX) X(_PC_MAX_CANON) X(_PC_MAX_INPUT)
X(_PC_NAME_MAX) X(_PC_PATH_MAX) X(_PC_PIPE_BUF)
X(_PC_CHOWN_RESTRICTED) X(_PC_NO_TRUNC) X(_PC_VDISABLE)
X(_PC_ASYNC_IO) X(_PC_PRIO_IO) X(_PC_SYNC_IO)
X(_PC_ALLOC_SIZE_MIN) X(_PC_FILESIZEBITS)
X(_PC_REC_INCR_XFER_SIZE) X(_PC_REC_MAX_XFER_SIZE)
X(_PC_REC_MIN_XFER_SIZE) X(_PC_REC_XFER_ALIGN)
X(_PC_SYMLINK_MAX) X(_PC_ACL_EXTENDED) X(_PC_ACL_PATH_MAX)
X(_PC_CAP_PRESENT) X(_PC_INF_PRESENT) X(_PC_MAC_PRESENT)
X(_PC_ACL_NFS4) X(_PC_MIN_HOLE_SIZE) XEND
};
static struct xlat rfork_flags[] = {
X(RFFDG) X(RFPROC) X(RFMEM) X(RFNOWAIT) X(RFCFDG) X(RFTHREAD)
X(RFSIGSHARE) X(RFLINUXTHPN) X(RFTSIGZMB) X(RFPPWAIT) XEND
};
static struct xlat wait_options[] = {
X(WNOHANG) X(WUNTRACED) X(WCONTINUED) X(WNOWAIT) X(WEXITED)
X(WTRAPPED) XEND
};
static struct xlat idtype_arg[] = {
X(P_PID) X(P_PPID) X(P_PGID) X(P_SID) X(P_CID) X(P_UID) X(P_GID)
X(P_ALL) X(P_LWPID) X(P_TASKID) X(P_PROJID) X(P_POOLID) X(P_JAILID)
X(P_CTID) X(P_CPUID) X(P_PSETID) XEND
};
static struct xlat procctl_arg[] = {
X(PROC_SPROTECT) XEND
};
static struct xlat umtx_ops[] = {
X(UMTX_OP_RESERVED0) X(UMTX_OP_RESERVED1) X(UMTX_OP_WAIT)
X(UMTX_OP_WAKE) X(UMTX_OP_MUTEX_TRYLOCK) X(UMTX_OP_MUTEX_LOCK)
X(UMTX_OP_MUTEX_UNLOCK) X(UMTX_OP_SET_CEILING) X(UMTX_OP_CV_WAIT)
X(UMTX_OP_CV_SIGNAL) X(UMTX_OP_CV_BROADCAST) X(UMTX_OP_WAIT_UINT)
X(UMTX_OP_RW_RDLOCK) X(UMTX_OP_RW_WRLOCK) X(UMTX_OP_RW_UNLOCK)
X(UMTX_OP_WAIT_UINT_PRIVATE) X(UMTX_OP_WAKE_PRIVATE)
X(UMTX_OP_MUTEX_WAIT) X(UMTX_OP_MUTEX_WAKE) X(UMTX_OP_SEM_WAIT)
X(UMTX_OP_SEM_WAKE) X(UMTX_OP_NWAKE_PRIVATE) X(UMTX_OP_MUTEX_WAKE2)
X(UMTX_OP_SEM2_WAIT) X(UMTX_OP_SEM2_WAKE)
XEND
};
static struct xlat at_flags[] = {
X(AT_EACCESS) X(AT_SYMLINK_NOFOLLOW) X(AT_SYMLINK_FOLLOW)
X(AT_REMOVEDIR) XEND
};
static struct xlat access_modes[] = {
X(R_OK) X(W_OK) X(X_OK) XEND
};
static struct xlat sysarch_ops[] = {
#if defined(__i386__) || defined(__amd64__)
X(I386_GET_LDT) X(I386_SET_LDT) X(I386_GET_IOPERM) X(I386_SET_IOPERM)
X(I386_VM86) X(I386_GET_FSBASE) X(I386_SET_FSBASE) X(I386_GET_GSBASE)
X(I386_SET_GSBASE) X(I386_GET_XFPUSTATE) X(AMD64_GET_FSBASE)
X(AMD64_SET_FSBASE) X(AMD64_GET_GSBASE) X(AMD64_SET_GSBASE)
X(AMD64_GET_XFPUSTATE)
#endif
XEND
};
static struct xlat linux_socketcall_ops[] = {
X(LINUX_SOCKET) X(LINUX_BIND) X(LINUX_CONNECT) X(LINUX_LISTEN)
X(LINUX_ACCEPT) X(LINUX_GETSOCKNAME) X(LINUX_GETPEERNAME)
X(LINUX_SOCKETPAIR) X(LINUX_SEND) X(LINUX_RECV) X(LINUX_SENDTO)
X(LINUX_RECVFROM) X(LINUX_SHUTDOWN) X(LINUX_SETSOCKOPT)
X(LINUX_GETSOCKOPT) X(LINUX_SENDMSG) X(LINUX_RECVMSG)
XEND
};
static struct xlat sigprocmask_ops[] = {
X(SIG_BLOCK) X(SIG_UNBLOCK) X(SIG_SETMASK)
XEND
};
#undef X
#undef XEND
/*
* Searches an xlat array for a value, and returns it if found. Otherwise
* return a string representation.
*/
static const char *
lookup(struct xlat *xlat, int val, int base)
{
static char tmp[16];
for (; xlat->str != NULL; xlat++)
if (xlat->val == val)
return (xlat->str);
switch (base) {
case 8:
sprintf(tmp, "0%o", val);
break;
case 16:
sprintf(tmp, "0x%x", val);
break;
case 10:
sprintf(tmp, "%u", val);
break;
default:
errx(1,"Unknown lookup base");
break;
}
return (tmp);
}
static const char *
xlookup(struct xlat *xlat, int val)
{
return (lookup(xlat, val, 16));
}
/* Searches an xlat array containing bitfield values. Remaining bits
set after removing the known ones are printed at the end:
IN|0x400 */
static char *
xlookup_bits(struct xlat *xlat, int val)
{
int len, rem;
static char str[512];
len = 0;
rem = val;
for (; xlat->str != NULL; xlat++) {
if ((xlat->val & rem) == xlat->val) {
/* don't print the "all-bits-zero" string unless all
bits are really zero */
if (xlat->val == 0 && val != 0)
continue;
len += sprintf(str + len, "%s|", xlat->str);
rem &= ~(xlat->val);
}
}
/* if we have leftover bits or didn't match anything */
if (rem || len == 0)
len += sprintf(str + len, "0x%x", rem);
if (len && str[len - 1] == '|')
len--;
str[len] = 0;
return (str);
}
/*
* If/when the list gets big, it might be desirable to do it
* as a hash table or binary search.
*/
struct syscall *
get_syscall(const char *name)
{
struct syscall *sc;
sc = syscalls;
if (name == NULL)
return (NULL);
while (sc->name) {
if (strcmp(name, sc->name) == 0)
return (sc);
sc++;
}
return (NULL);
}
/*
* get_struct
*
* Copy a fixed amount of bytes from the process.
*/
static int
get_struct(pid_t pid, void *offset, void *buf, int len)
{
struct ptrace_io_desc iorequest;
iorequest.piod_op = PIOD_READ_D;
iorequest.piod_offs = offset;
iorequest.piod_addr = buf;
iorequest.piod_len = len;
if (ptrace(PT_IO, pid, (caddr_t)&iorequest, 0) < 0)
return (-1);
return (0);
}
#define MAXSIZE 4096
/*
* get_string
* Copy a string from the process. Note that it is
* expected to be a C string, but if max is set, it will
* only get that much.
*/
static char *
get_string(pid_t pid, void *addr, int max)
{
struct ptrace_io_desc iorequest;
char *buf, *nbuf;
size_t offset, size, totalsize;
offset = 0;
if (max)
size = max + 1;
else {
/* Read up to the end of the current page. */
size = PAGE_SIZE - ((uintptr_t)addr % PAGE_SIZE);
if (size > MAXSIZE)
size = MAXSIZE;
}
totalsize = size;
buf = malloc(totalsize);
if (buf == NULL)
return (NULL);
for (;;) {
iorequest.piod_op = PIOD_READ_D;
iorequest.piod_offs = (char *)addr + offset;
iorequest.piod_addr = buf + offset;
iorequest.piod_len = size;
if (ptrace(PT_IO, pid, (caddr_t)&iorequest, 0) < 0) {
free(buf);
return (NULL);
}
if (memchr(buf + offset, '\0', size) != NULL)
return (buf);
offset += size;
if (totalsize < MAXSIZE && max == 0) {
size = MAXSIZE - totalsize;
if (size > PAGE_SIZE)
size = PAGE_SIZE;
nbuf = realloc(buf, totalsize + size);
if (nbuf == NULL) {
buf[totalsize - 1] = '\0';
return (buf);
}
buf = nbuf;
totalsize += size;
} else {
buf[totalsize - 1] = '\0';
return (buf);
}
}
}
static char *
strsig2(int sig)
{
static char tmp[sizeof(int) * 3 + 1];
char *ret;
ret = strsig(sig);
if (ret == NULL) {
snprintf(tmp, sizeof(tmp), "%d", sig);
ret = tmp;
}
return (ret);
}
static void
print_kevent(FILE *fp, struct kevent *ke, int input)
{
switch (ke->filter) {
case EVFILT_READ:
case EVFILT_WRITE:
case EVFILT_VNODE:
case EVFILT_PROC:
case EVFILT_TIMER:
case EVFILT_PROCDESC:
fprintf(fp, "%ju", (uintmax_t)ke->ident);
break;
case EVFILT_SIGNAL:
fputs(strsig2(ke->ident), fp);
break;
default:
fprintf(fp, "%p", (void *)ke->ident);
}
fprintf(fp, ",%s,%s,", xlookup(kevent_filters, ke->filter),
xlookup_bits(kevent_flags, ke->flags));
switch (ke->filter) {
case EVFILT_READ:
case EVFILT_WRITE:
fputs(xlookup_bits(kevent_rdwr_fflags, ke->fflags), fp);
break;
case EVFILT_VNODE:
fputs(xlookup_bits(kevent_vnode_fflags, ke->fflags), fp);
break;
case EVFILT_PROC:
case EVFILT_PROCDESC:
fputs(xlookup_bits(kevent_proc_fflags, ke->fflags), fp);
break;
case EVFILT_TIMER:
fputs(xlookup_bits(kevent_timer_fflags, ke->fflags), fp);
break;
case EVFILT_USER: {
int ctrl, data;
ctrl = ke->fflags & NOTE_FFCTRLMASK;
data = ke->fflags & NOTE_FFLAGSMASK;
if (input) {
fputs(xlookup(kevent_user_ffctrl, ctrl), fp);
if (ke->fflags & NOTE_TRIGGER)
fputs("|NOTE_TRIGGER", fp);
if (data != 0)
fprintf(fp, "|%#x", data);
} else {
fprintf(fp, "%#x", data);
}
break;
}
default:
fprintf(fp, "%#x", ke->fflags);
}
fprintf(fp, ",%p,%p", (void *)ke->data, (void *)ke->udata);
}
/*
* print_arg
* Converts a syscall argument into a string. Said string is
* allocated via malloc(), so needs to be free()'d. The file
* descriptor is for the process' memory (via /proc), and is used
* to get any data (where the argument is a pointer). sc is
* a pointer to the syscall description (see above); args is
* an array of all of the system call arguments.
*/
char *
print_arg(struct syscall_args *sc, unsigned long *args, long retval,
struct trussinfo *trussinfo)
{
FILE *fp;
char *tmp;
size_t tmplen;
pid_t pid;
fp = open_memstream(&tmp, &tmplen);
pid = trussinfo->pid;
switch (sc->type & ARG_MASK) {
case Hex:
fprintf(fp, "0x%x", (int)args[sc->offset]);
break;
case Octal:
fprintf(fp, "0%o", (int)args[sc->offset]);
break;
case Int:
fprintf(fp, "%d", (int)args[sc->offset]);
break;
case LongHex:
fprintf(fp, "0x%lx", args[sc->offset]);
break;
case Long:
fprintf(fp, "%ld", args[sc->offset]);
break;
case Name: {
/* NULL-terminated string. */
char *tmp2;
tmp2 = get_string(pid, (void*)args[sc->offset], 0);
fprintf(fp, "\"%s\"", tmp2);
free(tmp2);
break;
}
case BinString: {
/* Binary block of data that might have printable characters.
XXX If type|OUT, assume that the length is the syscall's
return value. Otherwise, assume that the length of the block
is in the next syscall argument. */
int max_string = trussinfo->strsize;
char tmp2[max_string+1], *tmp3;
int len;
int truncated = 0;
if (sc->type & OUT)
len = retval;
else
len = args[sc->offset + 1];
/* Don't print more than max_string characters, to avoid word
wrap. If we have to truncate put some ... after the string.
*/
if (len > max_string) {
len = max_string;
truncated = 1;
}
if (len && get_struct(pid, (void*)args[sc->offset], &tmp2, len)
!= -1) {
tmp3 = malloc(len * 4 + 1);
while (len) {
if (strvisx(tmp3, tmp2, len,
VIS_CSTYLE|VIS_TAB|VIS_NL) <= max_string)
break;
len--;
truncated = 1;
};
fprintf(fp, "\"%s\"%s", tmp3, truncated ?
"..." : "");
free(tmp3);
} else {
fprintf(fp, "0x%lx", args[sc->offset]);
}
break;
}
case StringArray: {
int num, size, i;
char *tmp2;
char *string;
char *strarray[100]; /* XXX This is ugly. */
if (get_struct(pid, (void *)args[sc->offset],
(void *)&strarray, sizeof(strarray)) == -1)
err(1, "get_struct %p", (void *)args[sc->offset]);
num = 0;
size = 0;
/* Find out how large of a buffer we'll need. */
while (strarray[num] != NULL) {
string = get_string(pid, (void*)strarray[num], 0);
size += strlen(string);
free(string);
num++;
}
size += 4 + (num * 4);
tmp = (char *)malloc(size);
tmp2 = tmp;
tmp2 += sprintf(tmp2, " [");
for (i = 0; i < num; i++) {
string = get_string(pid, (void*)strarray[i], 0);
tmp2 += sprintf(tmp2, " \"%s\"%c", string,
(i + 1 == num) ? ' ' : ',');
free(string);
}
tmp2 += sprintf(tmp2, "]");
break;
}
#ifdef __LP64__
case Quad:
fprintf(fp, "0x%lx", args[sc->offset]);
break;
#else
case Quad: {
unsigned long long ll;
ll = *(unsigned long long *)(args + sc->offset);
fprintf(fp, "0x%llx", ll);
break;
}
#endif
case Ptr:
fprintf(fp, "0x%lx", args[sc->offset]);
break;
case Readlinkres: {
char *tmp2;
if (retval == -1)
break;
tmp2 = get_string(pid, (void*)args[sc->offset], retval);
fprintf(fp, "\"%s\"", tmp2);
free(tmp2);
break;
}
case Ioctl: {
const char *temp = ioctlname(args[sc->offset]);
if (temp)
fputs(temp, fp);
else {
unsigned long arg = args[sc->offset];
fprintf(fp, "0x%lx { IO%s%s 0x%lx('%c'), %lu, %lu }",
arg, arg & IOC_OUT ? "R" : "",
arg & IOC_IN ? "W" : "", IOCGROUP(arg),
isprint(IOCGROUP(arg)) ? (char)IOCGROUP(arg) : '?',
arg & 0xFF, IOCPARM_LEN(arg));
}
break;
}
case Timespec: {
struct timespec ts;
if (get_struct(pid, (void *)args[sc->offset], &ts,
sizeof(ts)) != -1)
fprintf(fp, "{ %ld.%09ld }", (long)ts.tv_sec,
ts.tv_nsec);
else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Timespec2: {
struct timespec ts[2];
const char *sep;
unsigned int i;
if (get_struct(pid, (void *)args[sc->offset], &ts, sizeof(ts))
!= -1) {
fputs("{ ", fp);
sep = "";
for (i = 0; i < nitems(ts); i++) {
fputs(sep, fp);
sep = ", ";
switch (ts[i].tv_nsec) {
case UTIME_NOW:
fprintf(fp, "UTIME_NOW");
break;
case UTIME_OMIT:
fprintf(fp, "UTIME_OMIT");
break;
default:
fprintf(fp, "%ld.%09ld",
(long)ts[i].tv_sec, ts[i].tv_nsec);
break;
}
}
fputs(" }", fp);
} else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Timeval: {
struct timeval tv;
if (get_struct(pid, (void *)args[sc->offset], &tv, sizeof(tv))
!= -1)
fprintf(fp, "{ %ld.%06ld }", (long)tv.tv_sec,
tv.tv_usec);
else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Timeval2: {
struct timeval tv[2];
if (get_struct(pid, (void *)args[sc->offset], &tv, sizeof(tv))
!= -1)
fprintf(fp, "{ %ld.%06ld, %ld.%06ld }",
(long)tv[0].tv_sec, tv[0].tv_usec,
(long)tv[1].tv_sec, tv[1].tv_usec);
else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Itimerval: {
struct itimerval itv;
if (get_struct(pid, (void *)args[sc->offset], &itv,
sizeof(itv)) != -1)
fprintf(fp, "{ %ld.%06ld, %ld.%06ld }",
(long)itv.it_interval.tv_sec,
itv.it_interval.tv_usec,
(long)itv.it_value.tv_sec,
itv.it_value.tv_usec);
else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case LinuxSockArgs:
{
struct linux_socketcall_args largs;
if (get_struct(pid, (void *)args[sc->offset], (void *)&largs,
sizeof(largs)) != -1)
fprintf(fp, "{ %s, 0x%lx }",
lookup(linux_socketcall_ops, largs.what, 10),
(long unsigned int)largs.args);
else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Pollfd: {
/*
* XXX: A Pollfd argument expects the /next/ syscall argument
* to be the number of fds in the array. This matches the poll
* syscall.
*/
struct pollfd *pfd;
int numfds = args[sc->offset + 1];
size_t bytes = sizeof(struct pollfd) * numfds;
int i;
if ((pfd = malloc(bytes)) == NULL)
err(1, "Cannot malloc %zu bytes for pollfd array",
bytes);
if (get_struct(pid, (void *)args[sc->offset], pfd, bytes)
!= -1) {
fputs("{", fp);
for (i = 0; i < numfds; i++) {
fprintf(fp, " %d/%s", pfd[i].fd,
xlookup_bits(poll_flags, pfd[i].events));
}
fputs(" }", fp);
} else {
fprintf(fp, "0x%lx", args[sc->offset]);
}
free(pfd);
break;
}
case Fd_set: {
/*
* XXX: A Fd_set argument expects the /first/ syscall argument
* to be the number of fds in the array. This matches the
* select syscall.
*/
fd_set *fds;
int numfds = args[0];
size_t bytes = _howmany(numfds, _NFDBITS) * _NFDBITS;
int i;
if ((fds = malloc(bytes)) == NULL)
err(1, "Cannot malloc %zu bytes for fd_set array",
bytes);
if (get_struct(pid, (void *)args[sc->offset], fds, bytes)
!= -1) {
fputs("{", fp);
for (i = 0; i < numfds; i++) {
if (FD_ISSET(i, fds))
fprintf(fp, " %d", i);
}
fputs(" }", fp);
} else
fprintf(fp, "0x%lx", args[sc->offset]);
free(fds);
break;
}
case Signal:
fputs(strsig2(args[sc->offset]), fp);
break;
case Sigset: {
long sig;
sigset_t ss;
int i, first;
sig = args[sc->offset];
if (get_struct(pid, (void *)args[sc->offset], (void *)&ss,
sizeof(ss)) == -1) {
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
fputs("{ ", fp);
first = 1;
for (i = 1; i < sys_nsig; i++) {
if (sigismember(&ss, i)) {
fprintf(fp, "%s%s", !first ? "|" : "",
strsig(i));
first = 0;
}
}
if (!first)
fputc(' ', fp);
fputc('}', fp);
break;
}
case Sigprocmask: {
fputs(xlookup(sigprocmask_ops, args[sc->offset]), fp);
break;
}
case Fcntlflag: {
/* XXX output depends on the value of the previous argument */
switch (args[sc->offset-1]) {
case F_SETFD:
fputs(xlookup_bits(fcntlfd_arg, args[sc->offset]), fp);
break;
case F_SETFL:
fputs(xlookup_bits(fcntlfl_arg, args[sc->offset]), fp);
break;
case F_GETFD:
case F_GETFL:
case F_GETOWN:
break;
default:
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
break;
}
case Open:
fputs(xlookup_bits(open_flags, args[sc->offset]), fp);
break;
case Fcntl:
fputs(xlookup(fcntl_arg, args[sc->offset]), fp);
break;
case Mprot:
fputs(xlookup_bits(mprot_flags, args[sc->offset]), fp);
break;
case Mmapflags: {
int align, flags;
/*
* MAP_ALIGNED can't be handled by xlookup_bits(), so
* generate that string manually and prepend it to the
* string from xlookup_bits(). Have to be careful to
* avoid outputting MAP_ALIGNED|0 if MAP_ALIGNED is
* the only flag.
*/
flags = args[sc->offset] & ~MAP_ALIGNMENT_MASK;
align = args[sc->offset] & MAP_ALIGNMENT_MASK;
if (align != 0) {
if (align == MAP_ALIGNED_SUPER)
fputs("MAP_ALIGNED_SUPER", fp);
else
fprintf(fp, "MAP_ALIGNED(%d)",
align >> MAP_ALIGNMENT_SHIFT);
if (flags == 0)
break;
fputc('|', fp);
}
fputs(xlookup_bits(mmap_flags, flags), fp);
break;
}
case Whence:
fputs(xlookup(whence_arg, args[sc->offset]), fp);
break;
case Sockdomain:
fputs(xlookup(sockdomain_arg, args[sc->offset]), fp);
break;
case Socktype: {
int type, flags;
flags = args[sc->offset] & (SOCK_CLOEXEC | SOCK_NONBLOCK);
type = args[sc->offset] & ~flags;
fputs(xlookup(socktype_arg, type), fp);
if (flags & SOCK_CLOEXEC)
fprintf(fp, "|SOCK_CLOEXEC");
if (flags & SOCK_NONBLOCK)
fprintf(fp, "|SOCK_NONBLOCK");
break;
}
case Shutdown:
fputs(xlookup(shutdown_arg, args[sc->offset]), fp);
break;
case Resource:
fputs(xlookup(resource_arg, args[sc->offset]), fp);
break;
case Pathconf:
fputs(xlookup(pathconf_arg, args[sc->offset]), fp);
break;
case Rforkflags:
fputs(xlookup_bits(rfork_flags, args[sc->offset]), fp);
break;
case Sockaddr: {
struct sockaddr_storage ss;
char addr[64];
struct sockaddr_in *lsin;
struct sockaddr_in6 *lsin6;
struct sockaddr_un *sun;
struct sockaddr *sa;
u_char *q;
if (args[sc->offset] == 0) {
fputs("NULL", fp);
break;
}
/* yuck: get ss_len */
if (get_struct(pid, (void *)args[sc->offset], (void *)&ss,
sizeof(ss.ss_len) + sizeof(ss.ss_family)) == -1) {
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
/*
* If ss_len is 0, then try to guess from the sockaddr type.
* AF_UNIX may be initialized incorrectly, so always frob
* it by using the "right" size.
*/
if (ss.ss_len == 0 || ss.ss_family == AF_UNIX) {
switch (ss.ss_family) {
case AF_INET:
ss.ss_len = sizeof(*lsin);
break;
case AF_INET6:
ss.ss_len = sizeof(*lsin6);
break;
case AF_UNIX:
ss.ss_len = sizeof(*sun);
break;
default:
break;
}
}
if (ss.ss_len != 0 &&
get_struct(pid, (void *)args[sc->offset], (void *)&ss,
ss.ss_len) == -1) {
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
switch (ss.ss_family) {
case AF_INET:
lsin = (struct sockaddr_in *)&ss;
inet_ntop(AF_INET, &lsin->sin_addr, addr, sizeof addr);
fprintf(fp, "{ AF_INET %s:%d }", addr,
htons(lsin->sin_port));
break;
case AF_INET6:
lsin6 = (struct sockaddr_in6 *)&ss;
inet_ntop(AF_INET6, &lsin6->sin6_addr, addr,
sizeof addr);
fprintf(fp, "{ AF_INET6 [%s]:%d }", addr,
htons(lsin6->sin6_port));
break;
case AF_UNIX:
sun = (struct sockaddr_un *)&ss;
fprintf(fp, "{ AF_UNIX \"%s\" }", sun->sun_path);
break;
default:
sa = (struct sockaddr *)&ss;
fprintf(fp,
"{ sa_len = %d, sa_family = %d, sa_data = {",
(int)sa->sa_len, (int)sa->sa_family);
for (q = (u_char *)sa->sa_data;
q < (u_char *)sa + sa->sa_len; q++)
fprintf(fp, "%s 0x%02x",
q == (u_char *)sa->sa_data ? "" : ",",
*q);
fputs(" } }", fp);
}
break;
}
case Sigaction: {
struct sigaction sa;
if (get_struct(pid, (void *)args[sc->offset], &sa, sizeof(sa))
!= -1) {
fputs("{ ", fp);
if (sa.sa_handler == SIG_DFL)
fputs("SIG_DFL", fp);
else if (sa.sa_handler == SIG_IGN)
fputs("SIG_IGN", fp);
else
fprintf(fp, "%p", sa.sa_handler);
fprintf(fp, " %s ss_t }",
xlookup_bits(sigaction_flags, sa.sa_flags));
} else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Kevent: {
/*
* XXX XXX: the size of the array is determined by either the
* next syscall argument, or by the syscall returnvalue,
* depending on which argument number we are. This matches the
* kevent syscall, but luckily that's the only syscall that uses
* them.
*/
struct kevent *ke;
int numevents = -1;
size_t bytes;
int i;
if (sc->offset == 1)
numevents = args[sc->offset+1];
else if (sc->offset == 3 && retval != -1)
numevents = retval;
if (numevents >= 0) {
bytes = sizeof(struct kevent) * numevents;
if ((ke = malloc(bytes)) == NULL)
err(1,
"Cannot malloc %zu bytes for kevent array",
bytes);
} else
ke = NULL;
if (numevents >= 0 && get_struct(pid, (void *)args[sc->offset],
ke, bytes) != -1) {
fputc('{', fp);
for (i = 0; i < numevents; i++) {
fputc(' ', fp);
print_kevent(fp, &ke[i], sc->offset == 1);
}
fputs(" }", fp);
} else {
fprintf(fp, "0x%lx", args[sc->offset]);
}
free(ke);
break;
}
case Stat: {
struct stat st;
if (get_struct(pid, (void *)args[sc->offset], &st, sizeof(st))
!= -1) {
char mode[12];
strmode(st.st_mode, mode);
fprintf(fp,
"{ mode=%s,inode=%jd,size=%jd,blksize=%ld }", mode,
(intmax_t)st.st_ino, (intmax_t)st.st_size,
(long)st.st_blksize);
} else {
fprintf(fp, "0x%lx", args[sc->offset]);
}
break;
}
case Rusage: {
struct rusage ru;
if (get_struct(pid, (void *)args[sc->offset], &ru, sizeof(ru))
!= -1) {
fprintf(fp,
"{ u=%ld.%06ld,s=%ld.%06ld,in=%ld,out=%ld }",
(long)ru.ru_utime.tv_sec, ru.ru_utime.tv_usec,
(long)ru.ru_stime.tv_sec, ru.ru_stime.tv_usec,
ru.ru_inblock, ru.ru_oublock);
} else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Rlimit: {
struct rlimit rl;
if (get_struct(pid, (void *)args[sc->offset], &rl, sizeof(rl))
!= -1) {
fprintf(fp, "{ cur=%ju,max=%ju }",
rl.rlim_cur, rl.rlim_max);
} else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case ExitStatus: {
int status;
if (get_struct(pid, (void *)args[sc->offset], &status,
sizeof(status)) != -1) {
fputs("{ ", fp);
if (WIFCONTINUED(status))
fputs("CONTINUED", fp);
else if (WIFEXITED(status))
fprintf(fp, "EXITED,val=%d",
WEXITSTATUS(status));
else if (WIFSIGNALED(status))
fprintf(fp, "SIGNALED,sig=%s%s",
strsig2(WTERMSIG(status)),
WCOREDUMP(status) ? ",cored" : "");
else
fprintf(fp, "STOPPED,sig=%s",
strsig2(WTERMSIG(status)));
fputs(" }", fp);
} else
fprintf(fp, "0x%lx", args[sc->offset]);
break;
}
case Waitoptions:
fputs(xlookup_bits(wait_options, args[sc->offset]), fp);
break;
case Idtype:
fputs(xlookup(idtype_arg, args[sc->offset]), fp);
break;
case Procctl:
fputs(xlookup(procctl_arg, args[sc->offset]), fp);
break;
case Umtxop:
fputs(xlookup(umtx_ops, args[sc->offset]), fp);
break;
case Atfd:
if ((int)args[sc->offset] == AT_FDCWD)
fputs("AT_FDCWD", fp);
else
fprintf(fp, "%d", (int)args[sc->offset]);
break;
case Atflags:
fputs(xlookup_bits(at_flags, args[sc->offset]), fp);
break;
case Accessmode:
if (args[sc->offset] == F_OK)
fputs("F_OK", fp);
else
fputs(xlookup_bits(access_modes, args[sc->offset]), fp);
break;
case Sysarch:
fputs(xlookup(sysarch_ops, args[sc->offset]), fp);
break;
default:
errx(1, "Invalid argument type %d\n", sc->type & ARG_MASK);
}
fclose(fp);
return (tmp);
}
/*
* print_syscall
* Print (to outfile) the system call and its arguments. Note that
* nargs is the number of arguments (not the number of words; this is
* potentially confusing, I know).
*/
void
print_syscall(struct trussinfo *trussinfo, const char *name, int nargs,
char **s_args)
{
struct timespec timediff;
int i, len;
len = 0;
if (trussinfo->flags & FOLLOWFORKS)
len += fprintf(trussinfo->outfile, "%5d: ", trussinfo->pid);
if (name != NULL && (strcmp(name, "execve") == 0 ||
strcmp(name, "exit") == 0)) {
clock_gettime(CLOCK_REALTIME, &trussinfo->curthread->after);
}
if (trussinfo->flags & ABSOLUTETIMESTAMPS) {
timespecsubt(&trussinfo->curthread->after,
&trussinfo->start_time, &timediff);
len += fprintf(trussinfo->outfile, "%ld.%09ld ",
(long)timediff.tv_sec, timediff.tv_nsec);
}
if (trussinfo->flags & RELATIVETIMESTAMPS) {
timespecsubt(&trussinfo->curthread->after,
&trussinfo->curthread->before, &timediff);
len += fprintf(trussinfo->outfile, "%ld.%09ld ",
(long)timediff.tv_sec, timediff.tv_nsec);
}
len += fprintf(trussinfo->outfile, "%s(", name);
for (i = 0; i < nargs; i++) {
if (s_args[i])
len += fprintf(trussinfo->outfile, "%s", s_args[i]);
else
len += fprintf(trussinfo->outfile,
"<missing argument>");
len += fprintf(trussinfo->outfile, "%s", i < (nargs - 1) ?
"," : "");
}
len += fprintf(trussinfo->outfile, ")");
for (i = 0; i < 6 - (len / 8); i++)
fprintf(trussinfo->outfile, "\t");
}
void
print_syscall_ret(struct trussinfo *trussinfo, const char *name, int nargs,
char **s_args, int errorp, long retval, struct syscall *sc)
{
struct timespec timediff;
if (trussinfo->flags & COUNTONLY) {
if (!sc)
return;
clock_gettime(CLOCK_REALTIME, &trussinfo->curthread->after);
timespecsubt(&trussinfo->curthread->after,
&trussinfo->curthread->before, &timediff);
timespecadd(&sc->time, &timediff, &sc->time);
sc->ncalls++;
if (errorp)
sc->nerror++;
return;
}
print_syscall(trussinfo, name, nargs, s_args);
fflush(trussinfo->outfile);
if (errorp)
fprintf(trussinfo->outfile, " ERR#%ld '%s'\n", retval,
strerror(retval));
else {
/*
* Because pipe(2) has a special assembly glue to provide the
* libc API, we have to adjust retval.
*/
if (name != NULL && strcmp(name, "pipe") == 0)
retval = 0;
fprintf(trussinfo->outfile, " = %ld (0x%lx)\n", retval, retval);
}
}
void
print_summary(struct trussinfo *trussinfo)
{
struct timespec total = {0, 0};
struct syscall *sc;
int ncall, nerror;
fprintf(trussinfo->outfile, "%-20s%15s%8s%8s\n",
"syscall", "seconds", "calls", "errors");
ncall = nerror = 0;
for (sc = syscalls; sc->name != NULL; sc++)
if (sc->ncalls) {
fprintf(trussinfo->outfile, "%-20s%5jd.%09ld%8d%8d\n",
sc->name, (intmax_t)sc->time.tv_sec,
sc->time.tv_nsec, sc->ncalls, sc->nerror);
timespecadd(&total, &sc->time, &total);
ncall += sc->ncalls;
nerror += sc->nerror;
}
fprintf(trussinfo->outfile, "%20s%15s%8s%8s\n",
"", "-------------", "-------", "-------");
fprintf(trussinfo->outfile, "%-20s%5jd.%09ld%8d%8d\n",
"", (intmax_t)total.tv_sec, total.tv_nsec, ncall, nerror);
}