/* pinfo.h: process table info Copyright 2000, 2001, 2002 Red Hat, Inc. This file is part of Cygwin. This software is a copyrighted work licensed under the terms of the Cygwin license. Please consult the file "CYGWIN_LICENSE" for details. */ #ifndef _PINFO_H #define _PINFO_H /* Signal constants (have to define them here, unfortunately) */ enum { __SIGFLUSH = -2, __SIGSTRACE = -1, __SIGUNUSED = 0, __SIGOFFSET = 2 }; #define PSIZE 63 #include #include "thread.h" class _pinfo { public: /* Cygwin pid */ pid_t pid; /* Various flags indicating the state of the process. See PID_ constants below. */ DWORD process_state; /* If hProcess is set, it's because it came from a CreateProcess call. This means it's process relative to the thing which created the process. That's ok because we only use this handle from the parent. */ HANDLE hProcess; #define PINFO_REDIR_SIZE ((char *) &myself.procinfo->hProcess - (char *) myself.procinfo) /* Handle associated with initial Windows pid which started it all. */ HANDLE pid_handle; /* Handle to the logical parent of this pid. */ HANDLE ppid_handle; /* Parent process id. */ pid_t ppid; /* dwProcessId contains the processid used for sending signals. It * will be reset in a child process when it is capable of receiving * signals. */ DWORD dwProcessId; /* Used to spawn a child for fork(), among other things. */ char progname[MAX_PATH]; /* User information. The information is derived from the GetUserName system call, with the name looked up in /etc/passwd and assigned a default value if not found. This data resides in the shared data area (allowing tasks to store whatever they want here) so it's for informational purposes only. */ __uid32_t uid; /* User ID */ __gid32_t gid; /* Group ID */ pid_t pgid; /* Process group ID */ pid_t sid; /* Session ID */ int ctty; /* Control tty */ bool has_pgid_children;/* True if we've forked or spawned children with our GID. */ /* Resources used by process. */ long start_time; struct rusage rusage_self; struct rusage rusage_children; /* Non-zero if process was stopped by a signal. */ char stopsig; void exit (UINT n, bool norecord = 0) __attribute__ ((noreturn, regparm(2))); inline void set_has_pgid_children () { if (pgid == pid) has_pgid_children = 1; } inline void set_has_pgid_children (bool val) {has_pgid_children = val;} inline struct sigaction& getsig (int sig) { return thread2signal ? thread2signal->sigs[sig] : sigs[sig]; } inline void copysigs (_pinfo *p) {memcpy (sigs, p->sigs, sizeof (sigs));} inline sigset_t& getsigmask () { return thread2signal ? *thread2signal->sigmask : sig_mask; } inline void setsigmask (sigset_t mask) { if (thread2signal) *(thread2signal->sigmask) = mask; sig_mask = mask; } inline LONG* getsigtodo (int sig) {return _sigtodo + __SIGOFFSET + sig;} inline HANDLE getthread2signal () { return thread2signal ? thread2signal->win32_obj_id : hMainThread; } inline void setthread2signal (void *thr) {thread2signal = (pthread *) thr;} private: struct sigaction sigs[NSIG]; sigset_t sig_mask; /* one set for everything to ignore. */ LONG _sigtodo[NSIG + __SIGOFFSET]; pthread *thread2signal; // NULL means means thread any other means a pthread }; class pinfo { HANDLE h; _pinfo *procinfo; bool destroy; public: void init (pid_t n, DWORD create = 0, HANDLE h = NULL) __attribute__ ((regparm(3))); pinfo () {} pinfo (_pinfo *x): procinfo (x) {} pinfo (pid_t n) {init (n);} pinfo (pid_t n, int create) {init (n, create);} void release (); ~pinfo () { if (destroy && procinfo) release (); } _pinfo *operator -> () const {return procinfo;} int operator == (pinfo *x) const {return x->procinfo == procinfo;} int operator == (pinfo &x) const {return x.procinfo == procinfo;} int operator == (void *x) const {return procinfo == x;} int operator == (int x) const {return (int) procinfo == (int) x;} int operator == (char *x) const {return (char *) procinfo == x;} _pinfo *operator * () const {return procinfo;} operator _pinfo * () const {return procinfo;} // operator bool () const {return (int) h;} #ifndef _SIGPROC_H int remember () {system_printf ("remember is not here"); return 0;} #else int remember () { int res = proc_subproc (PROC_ADDCHILD, (DWORD) this); destroy = res ? false : true; return res; } #endif HANDLE shared_handle () {return h;} }; #define ISSTATE(p, f) (!!((p)->process_state & f)) #define NOTSTATE(p, f) (!((p)->process_state & f)) class winpids { DWORD *pidlist; DWORD npidlist; pinfo *pinfolist; DWORD (winpids::* enum_processes) (bool winpid); DWORD enum_init (bool winpid); DWORD enumNT (bool winpid); DWORD enum9x (bool winpid); void add (DWORD& nelem, bool, DWORD pid); public: DWORD npids; inline void reset () { npids = 0; release (); } void init (bool winpid); winpids (int): enum_processes (&winpids::enum_init) { reset (); } winpids (): pidlist (NULL), npidlist (0), pinfolist (NULL), enum_processes (&winpids::enum_init), npids (0) { init (0); } inline DWORD& winpid (int i) const {return pidlist[i];} inline _pinfo *operator [] (int i) const {return (_pinfo *) pinfolist[i];} ~winpids (); void release (); }; extern __inline pid_t cygwin_pid (pid_t pid) { return (pid_t) (wincap.has_negative_pids ()) ? -(int) pid : pid; } void __stdcall pinfo_init (char **, int); void __stdcall set_myself (pid_t pid, HANDLE h = NULL); extern pinfo myself; #define _P_VFORK 0 extern void __stdcall pinfo_fixup_after_fork (); extern HANDLE hexec_proc; /* For mmaps across fork(). */ int __stdcall fixup_mmaps_after_fork (HANDLE parent); /* for shm areas across fork (). */ int __stdcall fixup_shms_after_fork (); void __stdcall fill_rusage (struct rusage *, HANDLE); void __stdcall add_rusage (struct rusage *, struct rusage *); #endif /*_PINFO_H*/