/* * 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #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 | OUT, 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 = "readlink", .ret_type = 1, .nargs = 3, .args = { { Name, 0 } , { Readlinkres | OUT, 1 }, { Int, 2 } } }, { .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 = "mkdir", .ret_type = 1, .nargs = 2, .args = { { Name, 0 } , { Octal, 1 } } }, { .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 = "unlink", .ret_type = 0, .nargs = 1, .args = { { Name, 0 } } }, { .name = "chdir", .ret_type = 0, .nargs = 1, .args = { { Name, 0 } } }, { .name = "chroot", .ret_type = 0, .nargs = 1, .args = { { Name, 0 } } }, { .name = "mknod", .ret_type = 0, .nargs = 3, .args = { { Name, 0 }, { Octal, 1 }, { Int, 3 } } }, { .name = "chmod", .ret_type = 0, .nargs = 2, .args = { { Name, 0 }, { Octal, 1 } } }, { .name = "chown", .ret_type = 0, .nargs = 3, .args = { { Name, 0 }, { Int, 1 }, { Int, 2 } } }, { .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 = "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 }, { Int, 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 }, { Int, 1 } } }, { .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 = "connect", .ret_type = 1, .nargs = 3, .args = { { Int, 0 }, { Sockaddr | IN, 1 }, { Int, 2 } } }, { .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 = "_umtx_lock", .ret_type = 0, .nargs = 1, .args = { { Umtx, 0 } } }, { .name = "_umtx_unlock", .ret_type = 0, .nargs = 1, .args = { { Umtx, 0 } } }, { .name = "sigprocmask", .ret_type = 0, .nargs = 3, .args = { { Sigprocmask, 0 }, { Sigset, 1 }, { Sigset | OUT, 2 } } }, { .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 }, { Timeval | IN, 1 } } }, { .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 = "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 = "symlink", .ret_type = 1, .nargs = 2, .args = { { Name , 0 } , { Name, 1 } } }, { .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 = "_umtx_op", .ret_type = 1, .nargs = 5, .args = { { Ptr, 0 }, { Umtxop, 1 }, { LongHex, 2 }, { Ptr, 3 }, { Ptr, 4 } } }, { .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_FS) X(EVFILT_READ) 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_FLAG1) X(EV_ERROR) X(EV_EOF) 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_RENAME) X(MAP_NORESERVE) X(MAP_RESERVED0080) X(MAP_RESERVED0100) X(MAP_HASSEMAPHORE) X(MAP_STACK) X(MAP_NOSYNC) X(MAP_ANON) 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) 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_GETLK) X(F_SETLK) X(F_SETLKW) 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(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) 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) 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) 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) XEND }; static struct xlat rfork_flags[] = { X(RFPROC) X(RFNOWAIT) X(RFFDG) X(RFCFDG) X(RFTHREAD) X(RFMEM) X(RFSIGSHARE) X(RFTSIGZMB) X(RFLINUXTHPN) 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_LOCK) X(UMTX_OP_UNLOCK) 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) 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 #define BLOCKSIZE 1024 /* * 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 *offset, int max) { struct ptrace_io_desc iorequest; char *buf; int diff, i, size, totalsize; diff = 0; totalsize = size = max ? (max + 1) : BLOCKSIZE; buf = malloc(totalsize); if (buf == NULL) return (NULL); for (;;) { diff = totalsize - size; iorequest.piod_op = PIOD_READ_D; iorequest.piod_offs = (char *)offset + diff; iorequest.piod_addr = buf + diff; iorequest.piod_len = size; if (ptrace(PT_IO, pid, (caddr_t)&iorequest, 0) < 0) { free(buf); return (NULL); } for (i = 0 ; i < size; i++) { if (buf[diff + i] == '\0') return (buf); } if (totalsize < MAXSIZE - BLOCKSIZE && max == 0) { totalsize += BLOCKSIZE; buf = realloc(buf, totalsize); size = BLOCKSIZE; } else { buf[totalsize - 1] = '\0'; return (buf); } } } static char * strsig2(int sig) { char *tmp; tmp = strsig(sig); if (tmp == NULL) asprintf(&tmp, "%d", sig); return (tmp); } /* * 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) { char *tmp; pid_t pid; tmp = NULL; pid = trussinfo->pid; switch (sc->type & ARG_MASK) { case Hex: asprintf(&tmp, "0x%x", (int)args[sc->offset]); break; case Octal: asprintf(&tmp, "0%o", (int)args[sc->offset]); break; case Int: asprintf(&tmp, "%d", (int)args[sc->offset]); break; case LongHex: asprintf(&tmp, "0x%lx", args[sc->offset]); break; case Name: { /* NULL-terminated string. */ char *tmp2; tmp2 = get_string(pid, (void*)args[sc->offset], 0); asprintf(&tmp, "\"%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; }; asprintf(&tmp, "\"%s\"%s", tmp3, truncated ? "..." : ""); free(tmp3); } else { asprintf(&tmp, "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: asprintf(&tmp, "0x%lx", args[sc->offset]); break; #else case Quad: { unsigned long long ll; ll = *(unsigned long long *)(args + sc->offset); asprintf(&tmp, "0x%llx", ll); break; } #endif case Ptr: asprintf(&tmp, "0x%lx", args[sc->offset]); break; case Readlinkres: { char *tmp2; if (retval == -1) { tmp = strdup(""); break; } tmp2 = get_string(pid, (void*)args[sc->offset], retval); asprintf(&tmp, "\"%s\"", tmp2); free(tmp2); break; } case Ioctl: { const char *temp = ioctlname(args[sc->offset]); if (temp) tmp = strdup(temp); else { unsigned long arg = args[sc->offset]; asprintf(&tmp, "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 Umtx: { struct umtx umtx; if (get_struct(pid, (void *)args[sc->offset], &umtx, sizeof(umtx)) != -1) asprintf(&tmp, "{ 0x%lx }", (long)umtx.u_owner); else asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case Timespec: { struct timespec ts; if (get_struct(pid, (void *)args[sc->offset], &ts, sizeof(ts)) != -1) asprintf(&tmp, "{%ld.%09ld }", (long)ts.tv_sec, ts.tv_nsec); else asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case Timeval: { struct timeval tv; if (get_struct(pid, (void *)args[sc->offset], &tv, sizeof(tv)) != -1) asprintf(&tmp, "{%ld.%06ld }", (long)tv.tv_sec, tv.tv_usec); else asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case Timeval2: { struct timeval tv[2]; if (get_struct(pid, (void *)args[sc->offset], &tv, sizeof(tv)) != -1) asprintf(&tmp, "{%ld.%06ld, %ld.%06ld }", (long)tv[0].tv_sec, tv[0].tv_usec, (long)tv[1].tv_sec, tv[1].tv_usec); else asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case Itimerval: { struct itimerval itv; if (get_struct(pid, (void *)args[sc->offset], &itv, sizeof(itv)) != -1) asprintf(&tmp, "{%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 asprintf(&tmp, "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) { err(1, "get_struct %p", (void *)args[sc->offset]); } const char *what; char buf[30]; switch (largs.what) { case LINUX_SOCKET: what = "LINUX_SOCKET"; break; case LINUX_BIND: what = "LINUX_BIND"; break; case LINUX_CONNECT: what = "LINUX_CONNECT"; break; case LINUX_LISTEN: what = "LINUX_LISTEN"; break; case LINUX_ACCEPT: what = "LINUX_ACCEPT"; break; case LINUX_GETSOCKNAME: what = "LINUX_GETSOCKNAME"; break; case LINUX_GETPEERNAME: what = "LINUX_GETPEERNAME"; break; case LINUX_SOCKETPAIR: what = "LINUX_SOCKETPAIR"; break; case LINUX_SEND: what = "LINUX_SEND"; break; case LINUX_RECV: what = "LINUX_RECV"; break; case LINUX_SENDTO: what = "LINUX_SENDTO"; break; case LINUX_RECVFROM: what = "LINUX_RECVFROM"; break; case LINUX_SHUTDOWN: what = "LINUX_SHUTDOWN"; break; case LINUX_SETSOCKOPT: what = "LINUX_SETSOCKOPT"; break; case LINUX_GETSOCKOPT: what = "LINUX_GETSOCKOPT"; break; case LINUX_SENDMSG: what = "LINUX_SENDMSG"; break; case LINUX_RECVMSG: what = "LINUX_RECVMSG"; break; default: sprintf(buf, "%d", largs.what); what = buf; break; } asprintf(&tmp, "(0x%lx)%s, 0x%lx", args[sc->offset], what, (long unsigned int)largs.args); 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]; int bytes = sizeof(struct pollfd) * numfds; int i, tmpsize, u, used; const int per_fd = 100; if ((pfd = malloc(bytes)) == NULL) err(1, "Cannot malloc %d bytes for pollfd array", bytes); if (get_struct(pid, (void *)args[sc->offset], pfd, bytes) != -1) { used = 0; tmpsize = 1 + per_fd * numfds + 2; if ((tmp = malloc(tmpsize)) == NULL) err(1, "Cannot alloc %d bytes for poll output", tmpsize); tmp[used++] = '{'; for (i = 0; i < numfds; i++) { u = snprintf(tmp + used, per_fd, "%s%d/%s", i > 0 ? " " : "", pfd[i].fd, xlookup_bits(poll_flags, pfd[i].events)); if (u > 0) used += u < per_fd ? u : per_fd; } tmp[used++] = '}'; tmp[used++] = '\0'; } else { asprintf(&tmp, "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]; int bytes = _howmany(numfds, _NFDBITS) * _NFDBITS; int i, tmpsize, u, used; const int per_fd = 20; if ((fds = malloc(bytes)) == NULL) err(1, "Cannot malloc %d bytes for fd_set array", bytes); if (get_struct(pid, (void *)args[sc->offset], fds, bytes) != -1) { used = 0; tmpsize = 1 + numfds * per_fd + 2; if ((tmp = malloc(tmpsize)) == NULL) err(1, "Cannot alloc %d bytes for fd_set " "output", tmpsize); tmp[used++] = '{'; for (i = 0; i < numfds; i++) { if (FD_ISSET(i, fds)) { u = snprintf(tmp + used, per_fd, "%d ", i); if (u > 0) used += u < per_fd ? u : per_fd; } } if (tmp[used-1] == ' ') used--; tmp[used++] = '}'; tmp[used++] = '\0'; } else asprintf(&tmp, "0x%lx", args[sc->offset]); free(fds); break; } case Signal: tmp = strsig2(args[sc->offset]); break; case Sigset: { long sig; sigset_t ss; int i, used; char *signame; sig = args[sc->offset]; if (get_struct(pid, (void *)args[sc->offset], (void *)&ss, sizeof(ss)) == -1) { asprintf(&tmp, "0x%lx", args[sc->offset]); break; } tmp = malloc(sys_nsig * 8); /* 7 bytes avg per signal name */ used = 0; for (i = 1; i < sys_nsig; i++) { if (sigismember(&ss, i)) { signame = strsig(i); used += sprintf(tmp + used, "%s|", signame); free(signame); } } if (used) tmp[used-1] = 0; else strcpy(tmp, "0x0"); break; } case Sigprocmask: { switch (args[sc->offset]) { #define S(a) case a: tmp = strdup(#a); break; S(SIG_BLOCK); S(SIG_UNBLOCK); S(SIG_SETMASK); #undef S } if (tmp == NULL) asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case Fcntlflag: { /* XXX output depends on the value of the previous argument */ switch (args[sc->offset-1]) { case F_SETFD: tmp = strdup(xlookup_bits(fcntlfd_arg, args[sc->offset])); break; case F_SETFL: tmp = strdup(xlookup_bits(fcntlfl_arg, args[sc->offset])); break; case F_GETFD: case F_GETFL: case F_GETOWN: tmp = strdup(""); break; default: asprintf(&tmp, "0x%lx", args[sc->offset]); break; } break; } case Open: tmp = strdup(xlookup_bits(open_flags, args[sc->offset])); break; case Fcntl: tmp = strdup(xlookup(fcntl_arg, args[sc->offset])); break; case Mprot: tmp = strdup(xlookup_bits(mprot_flags, args[sc->offset])); break; case Mmapflags: { char *base, *alignstr; 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) alignstr = strdup("MAP_ALIGNED_SUPER"); else asprintf(&alignstr, "MAP_ALIGNED(%d)", align >> MAP_ALIGNMENT_SHIFT); if (flags == 0) { tmp = alignstr; break; } } else alignstr = NULL; base = strdup(xlookup_bits(mmap_flags, flags)); if (alignstr == NULL) { tmp = base; break; } asprintf(&tmp, "%s|%s", alignstr, base); free(alignstr); free(base); break; } case Whence: tmp = strdup(xlookup(whence_arg, args[sc->offset])); break; case Sockdomain: tmp = strdup(xlookup(sockdomain_arg, args[sc->offset])); break; case Socktype: tmp = strdup(xlookup(socktype_arg, args[sc->offset])); break; case Shutdown: tmp = strdup(xlookup(shutdown_arg, args[sc->offset])); break; case Resource: tmp = strdup(xlookup(resource_arg, args[sc->offset])); break; case Pathconf: tmp = strdup(xlookup(pathconf_arg, args[sc->offset])); break; case Rforkflags: tmp = strdup(xlookup_bits(rfork_flags, args[sc->offset])); 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; char *p; u_char *q; int i; if (args[sc->offset] == 0) { asprintf(&tmp, "NULL"); break; } /* yuck: get ss_len */ if (get_struct(pid, (void *)args[sc->offset], (void *)&ss, sizeof(ss.ss_len) + sizeof(ss.ss_family)) == -1) err(1, "get_struct %p", (void *)args[sc->offset]); /* * 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_UNIX: ss.ss_len = sizeof(*sun); break; default: /* hurrrr */ break; } } if (get_struct(pid, (void *)args[sc->offset], (void *)&ss, ss.ss_len) == -1) { err(2, "get_struct %p", (void *)args[sc->offset]); } switch (ss.ss_family) { case AF_INET: lsin = (struct sockaddr_in *)&ss; inet_ntop(AF_INET, &lsin->sin_addr, addr, sizeof addr); asprintf(&tmp, "{ 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); asprintf(&tmp, "{ AF_INET6 [%s]:%d }", addr, htons(lsin6->sin6_port)); break; case AF_UNIX: sun = (struct sockaddr_un *)&ss; asprintf(&tmp, "{ AF_UNIX \"%s\" }", sun->sun_path); break; default: sa = (struct sockaddr *)&ss; asprintf(&tmp, "{ sa_len = %d, sa_family = %d, sa_data " "= {%n%*s } }", (int)sa->sa_len, (int)sa->sa_family, &i, 6 * (int)(sa->sa_len - ((char *)&sa->sa_data - (char *)sa)), ""); if (tmp != NULL) { p = tmp + i; for (q = (u_char *)&sa->sa_data; q < (u_char *)sa + sa->sa_len; q++) p += sprintf(p, " %#02x,", *q); } } break; } case Sigaction: { struct sigaction sa; char *hand; const char *h; if (get_struct(pid, (void *)args[sc->offset], &sa, sizeof(sa)) != -1) { asprintf(&hand, "%p", sa.sa_handler); if (sa.sa_handler == SIG_DFL) h = "SIG_DFL"; else if (sa.sa_handler == SIG_IGN) h = "SIG_IGN"; else h = hand; asprintf(&tmp, "{ %s %s ss_t }", h, xlookup_bits(sigaction_flags, sa.sa_flags)); free(hand); } else asprintf(&tmp, "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; int bytes = 0; int i, tmpsize, u, used; const int per_ke = 100; 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 %d bytes for kevent array", bytes); if (numevents >= 0 && get_struct(pid, (void *)args[sc->offset], ke, bytes) != -1) { used = 0; tmpsize = 1 + per_ke * numevents + 2; if ((tmp = malloc(tmpsize)) == NULL) err(1, "Cannot alloc %d bytes for kevent " "output", tmpsize); tmp[used++] = '{'; for (i = 0; i < numevents; i++) { u = snprintf(tmp + used, per_ke, "%s%p,%s,%s,%d,%p,%p", i > 0 ? " " : "", (void *)ke[i].ident, xlookup(kevent_filters, ke[i].filter), xlookup_bits(kevent_flags, ke[i].flags), ke[i].fflags, (void *)ke[i].data, (void *)ke[i].udata); if (u > 0) used += u < per_ke ? u : per_ke; } tmp[used++] = '}'; tmp[used++] = '\0'; } else { asprintf(&tmp, "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); asprintf(&tmp, "{ mode=%s,inode=%jd,size=%jd,blksize=%ld }", mode, (intmax_t)st.st_ino, (intmax_t)st.st_size, (long)st.st_blksize); } else { asprintf(&tmp, "0x%lx", args[sc->offset]); } break; } case Rusage: { struct rusage ru; if (get_struct(pid, (void *)args[sc->offset], &ru, sizeof(ru)) != -1) { asprintf(&tmp, "{ 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 asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case Rlimit: { struct rlimit rl; if (get_struct(pid, (void *)args[sc->offset], &rl, sizeof(rl)) != -1) { asprintf(&tmp, "{ cur=%ju,max=%ju }", rl.rlim_cur, rl.rlim_max); } else asprintf(&tmp, "0x%lx", args[sc->offset]); break; } case ExitStatus: { char *signame; int status; signame = NULL; if (get_struct(pid, (void *)args[sc->offset], &status, sizeof(status)) != -1) { if (WIFCONTINUED(status)) tmp = strdup("{ CONTINUED }"); else if (WIFEXITED(status)) asprintf(&tmp, "{ EXITED,val=%d }", WEXITSTATUS(status)); else if (WIFSIGNALED(status)) asprintf(&tmp, "{ SIGNALED,sig=%s%s }", signame = strsig2(WTERMSIG(status)), WCOREDUMP(status) ? ",cored" : ""); else asprintf(&tmp, "{ STOPPED,sig=%s }", signame = strsig2(WTERMSIG(status))); } else asprintf(&tmp, "0x%lx", args[sc->offset]); free(signame); break; } case Waitoptions: tmp = strdup(xlookup_bits(wait_options, args[sc->offset])); break; case Idtype: tmp = strdup(xlookup(idtype_arg, args[sc->offset])); break; case Procctl: tmp = strdup(xlookup(procctl_arg, args[sc->offset])); break; case Umtxop: tmp = strdup(xlookup(umtx_ops, args[sc->offset])); break; default: errx(1, "Invalid argument type %d\n", sc->type & ARG_MASK); } 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, ""); 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); }