/* $RCSfile: runargv.c,v $
-- $Revision: 1.11.6.6 $
-- last change: $Author: vq $ $Date: 2007/10/06 14:33:06 $
--
-- SYNOPSIS
-- Invoke a sub process.
--
-- DESCRIPTION
-- Use the standard methods of executing a sub process.
--
-- AUTHOR
-- Dennis Vadura, dvadura@dmake.wticorp.com
--
-- WWW
-- http://dmake.wticorp.com/
--
-- COPYRIGHT
-- Copyright (c) 1996,1997 by WTI Corp. All rights reserved.
--
-- This program is NOT free software; you can redistribute it and/or
-- modify it under the terms of the Software License Agreement Provided
-- in the file <distribution-root>/readme/license.txt.
--
-- LOG
-- Use cvs log to obtain detailed change logs.
*/
/*
This file (runargv.c) provides all the parallel process handling routines
for dmake on unix like operating systems. The following text briefly
describes the process flow.
Exec_commands() [make.c] builds the recipes associated to the given target.
They are build sequentially in a loop that calls Do_cmnd() for each of them.
Do_cmnd() [sysintf.c] feeds the given command or command group to runargv().
The following flowchart decripes the process flow starting with runargv,
descriptions for each of the functions are following.
+--------------------------------+
| runargv | <+
+--------------------------------+ |
| ^ |
| | returns if |
| calls | wfc is false |
v | |
+--------------------------------+ |
| _add_child | |
+--------------------------------+ |
| ^ |
| calls if | | if another process
| wfc is true | returns | is queued:
v | | recursive call
+--------------------------------+ |
| Wait_for_Child | |
+--------------------------------+ |
| ^ |
| | process queue |
| calls | is empty |
v | |
+--------------------------------+ |
| _finished_child | -+
+--------------------------------+
runargv() [unix/runargv] The runargv function manages up to MAXPROCESS
process queues (_procs[i]) for parallel process execution and hands
the actual commands down to the operating system.
Each of the process queues handles the sequential execution of commands
that belong to that process queue. Usually this means the sequential
execution of the recipe lines that belong to one target.
Even in non parallel builds (MAXPROCESS==1) child processes are
created and handled.
If recipes for a target are currently running attach them to the
corresponding process queue (_procs[i]) of that target and return.
If the maximum number (MAXPROCESS) of concurrently running queues is
reached use Wait_for_child(?, -1) to wait for a process queue to become
available.
New child processes are started using:
spawn: posix_spawnp (POSIX) or spawnvp (cygwin).
fork/execvp: Create a client process with fork and run the command
with execvp.
The parent calls _add_child() to track the child.
_add_child(..., wfc) [unix/runargv] creates (or reuses) a process queue
and enters the child's parameters.
If wfc (wait for completion) is TRUE the function calls
Wait_for_child to wait for the whole process queue to be finished.
Wait_for_child(abort_flg, pqid) [unix/runargv] waits either for the current
process from process queue pqid to finish or if the W_WFC attribute is
set for all entries of that process queue (recursively) to finish.
All finished processes are handled by calling _finished_child() for each
of them.
If pqid == -1 wait for the next process to finish but honor the A_WFC
attribute of that process (queue) and wait for the whole queue if needed.
If abort_flg is TRUE no further processes will be added to any process
queue.
If a pqid is given but a process from another process queue finishes
first that process is handled and A_WFC is also honored.
All finished processes are processed until the process from the given pqid
is reached or gone (might have been handled while finishing another process
queue).
_finished_child(pid, status) [unix/runargv] handles the finished child. If
there are more commands in the corresponding process queue start the next
with runargv().
*/
#include <signal.h>
#include "extern.h"
#ifdef HAVE_WAIT_H
# include <wait.h>
#else
# ifdef HAVE_SYS_WAIT_H
# include <sys/wait.h>
# endif
#endif
#if HAVE_SPAWN_H && ENABLE_SPAWN
# include <spawn.h>
#endif
#if __CYGWIN__ && ENABLE_SPAWN
# include <process.h>
#endif
#ifdef __EMX__
# include <process.h>
#define _P_NOWAIT P_NOWAIT
#endif
#include "sysintf.h"
#if HAVE_ERRNO_H
# include <errno.h>
#else
extern int errno;
#endif
typedef struct prp {
char *prp_cmd;
int prp_group;
t_attr prp_attr;
int prp_last;
struct prp *prp_next;
} RCP, *RCPPTR;
typedef struct pr {
int pr_valid;
int pr_pid;
CELLPTR pr_target;
int pr_ignore;
int pr_last;
int pr_wfc;
RCPPTR pr_recipe;
RCPPTR pr_recipe_end;
char *pr_dir;
} PR;
static PR *_procs = NIL(PR); /* Array to hold concurrent processes. */
static int _procs_size = 0; /* Savegard to find MAXPROCESS changes. */
static int _proc_cnt = 0; /* Number of running processes. */
static int _abort_flg= FALSE;
static int _use_i = -1;
static int _add_child ANSI((int, CELLPTR, int, int, int));
static void _attach_cmd ANSI((char *, int, CELLPTR, t_attr, int));
static void _finished_child ANSI((int, int));
static int _running ANSI((CELLPTR));
#if ! HAVE_STRERROR
static char *
private_strerror (errnum)
int errnum;
{
#ifndef __APPLE__
#ifdef arm32
extern const char * const sys_errlist[];
#else
#if defined(linux) || defined(__FreeBSD__) || defined(__OpenBSD__)
extern const char * const sys_errlist[];
#else
extern char *sys_errlist[];
#endif
#endif
#endif
extern int sys_nerr;
if (errnum > 0 && errnum <= sys_nerr)
return sys_errlist[errnum];
return "Unknown system error";
}
#define strerror private_strerror
#endif /* HAVE_STRERROR */
PUBLIC int
runargv(target, group, last, cmnd_attr, cmd)/*
==============================================
Execute the command given by cmd.
Return 0 if the command executed and finished or
1 if the command started and is running.
*/
CELLPTR target;
int group;
int last;
t_attr cmnd_attr; /* Attributes for current cmnd. */
char **cmd; /* Simulate a reference to *cmd. */
{
int ignore = (cmnd_attr & A_IGNORE)!= 0; /* Ignore errors ('-'). */
int shell = (cmnd_attr & A_SHELL) != 0; /* Use shell ('+'). */
int mute = (cmnd_attr & A_MUTE) != 0; /* Mute output ('@@'). */
int wfc = (cmnd_attr & A_WFC) != 0; /* Wait for completion. */
int pid;
int st_pq = 0; /* Current _exec_shell target process index */
char *tcmd = *cmd; /* For saver/easier string arithmetic on *cmd. */
char **argv;
int old_stdout = -1; /* For shell escapes and */
int old_stderr = -1; /* @@-recipe silencing. */
int internal = 0; /* Used to indicate internal command. */
DB_ENTER( "runargv" );
/* Special handling for the shell function macro is required. If the
* currend command is called as part of a shell escape in a recipe make
* sure that all previous recipe lines of this target have finished. */
if( Is_exec_shell ) {
if( (st_pq = _running(Shell_exec_target)) != -1 ) {
RCPPTR rp;
/* Add WFC to _procs[st_pq]. */
_procs[st_pq].pr_wfc = TRUE;
/* Set also the A_WFC flag in the recipe attributes. */
for( rp = _procs[st_pq].pr_recipe ; rp != NIL(RCP); rp = rp->prp_next )
rp->prp_attr |= A_WFC;
Wait_for_child(FALSE, st_pq);
}
} else {
if( _running(target) != -1 /*&& Max_proc != 1*/ ) {
/* The command will be executed when the previous recipe
* line completes. */
_attach_cmd( *cmd, group, target, cmnd_attr, last );
DB_RETURN( 1 );
}
}
/* If all process array entries are used wait until we get a free
* slot. For Max_proc == 1 this forces sequential execution. */
while( _proc_cnt == Max_proc ) {
Wait_for_child(FALSE, -1);
}
/* Return immediately for empty line or noop command. */
if ( !*tcmd || /* empty line */
( strncmp(tcmd, "noop", 4) == 0 && /* noop command */
(iswhite(tcmd[4]) || tcmd[4] == '\0')) ) {
internal = 1;
}
else if( !shell && /* internal echo only if not in shell */
strncmp(tcmd, "echo", 4) == 0 &&
(iswhite(tcmd[4]) || tcmd[4] == '\0') ) {
int nl = 1;
tcmd = tcmd+4;
while( iswhite(*tcmd) ) ++tcmd;
if ( strncmp(tcmd,"-n",2 ) == 0) {
nl = 0;
tcmd = tcmd+2;
while( iswhite(*tcmd) ) ++tcmd;
}
/* redirect output for _exec_shell / @@-recipes. */
if( Is_exec_shell ) {
/* Add error checking? */
old_stdout = dup(1);
dup2( fileno(stdout_redir), 1 );
}
if( mute ) {
old_stderr = dup(2);
dup2( zerofd, 2 );
if( !Is_exec_shell ) {
old_stdout = dup(1);
dup2( zerofd, 1 );
}
}
printf("%s%s", tcmd, nl ? "\n" : "");
fflush(stdout);
/* Restore stdout/stderr if needed. */
if( old_stdout != -1 ) {
dup2(old_stdout, 1);
if( old_stderr != -1 )
dup2(old_stderr, 2);
}
internal = 1;
}
if ( internal ) {
/* Use _add_child() / _finished_child() with internal command. */
int cur_proc = _add_child(-1, target, ignore, last, FALSE);
_finished_child(-cur_proc, 0);
DB_RETURN( 0 );
}
/* Pack cmd in argument vector. */
argv = Pack_argv( group, shell, cmd );
/* Really spawn or fork a child. */
#if ENABLE_SPAWN && ( HAVE_SPAWN_H || __CYGWIN__ || __EMX__)
/* As no other childs are started while the output is redirected this
* is save. */
if( Is_exec_shell ) {
/* Add error checking? */
old_stdout = dup(1);
dup2( fileno(stdout_redir), 1 );
}
if( mute ) {
old_stderr = dup(2);
dup2( zerofd, 2 );
if( !Is_exec_shell ) {
old_stdout = dup(1);
dup2( zerofd, 1 );
}
}
#if defined( __CYGWIN__) || defined( __EMX__)
pid = spawnvp(_P_NOWAIT, argv[0], (const char**) argv);
#else /* __CYGWIN__ */
if (posix_spawnp (&pid, argv[0], NULL, NULL, argv, (char *)NULL))
pid = -1; /* posix_spawn failed */
#endif /* __CYGWIN__ */
if( old_stdout != -1 ) {
dup2(old_stdout, 1);
if( old_stderr != -1 )
dup2(old_stderr, 2);
}
if(pid == -1) {
/* spawn failed */
int cur_proc;
fprintf(stderr, "%s: Error executing '%s': %s",
Pname, argv[0], strerror(errno) );
if( ignore||Continue ) {
fprintf(stderr, " (Ignored)" );
}
fprintf(stderr, "\n");
/* Use _add_child() / _finished_child() to treat the failure
* gracefully, if so requested. */
cur_proc = _add_child(-1, target, ignore, last, FALSE);
_finished_child(cur_proc, SIGTERM);
/* _finished_child() aborts dmake if we are not told to
* ignore errors. If we reach the this point return 0 as
* errors are obviously ignored and indicate that the process
* finished. */
DB_RETURN( 0 );
} else {
_add_child(pid, target, ignore, last, wfc);
}
#else /* ENABLE_SPAWN && ... */
fflush(stdout);
switch( pid=fork() ){
case -1: /* fork failed */
Fatal("fork failed: %s: %s", argv[0], strerror( errno ));
case 0: /* child */
/* redirect output for _exec_shell / @@-recipes. */
if( Is_exec_shell ) {
/* Add error checking? */
old_stdout = dup(1);
dup2( fileno(stdout_redir), 1 );
}
if( mute ) {
old_stderr = dup(2);
dup2( zerofd, 2 );
if( !Is_exec_shell ) {
old_stdout = dup(1);
dup2( zerofd, 1 );
}
}
execvp(argv[0], argv);
/* restoring output to catch potential error output if execvp()
* failed. */
if( old_stdout != -1 ) {
dup2(old_stdout, 1);
if( old_stderr != -1 )
dup2(old_stderr, 2);
}
fprintf(stderr, "%s: Error executing '%s': %s",
Pname, argv[0], strerror(errno) );
if( ignore||Continue ) {
fprintf(stderr, " (Ignored)" );
}
fprintf(stderr, "\n");
kill(getpid(), SIGTERM);
/*NOTREACHED*/
Fatal("\nInternal Error - kill could't kill child %d.\n", getpid());
default: /* parent */
_add_child(pid, target, ignore, last, wfc);
}
#endif /* ENABLE_SPAWN && ... */
DB_RETURN( 1 );
}
PUBLIC int
Wait_for_child( abort_flg, pqid )/*
===================================
Wait for the next processes from process queue pqid to finish. All finished
processes are handled by calling _finished_child() for each of them.
If pqid == -1 wait for the next process to finish.
If abort_flg is TRUE no further processes will be added to any process
queue. The A_WFC attribute is honored, see the documentation at the top
of this file.
Return 0 if we successfully waited for a process and -1 if there was nothing
to wait for.
*/
int abort_flg;
int pqid;
{
int pid;
int wid;
int status;
/* Never wait for internal commands. */
int waitchild;
int is_exec_shell_status = Is_exec_shell;
if( !_procs ) {
/* No process was ever created, i.e. _procs is not yet initialized.
* Nothing to wait for. */
return -1;
}
if( pqid > Max_proc ) Fatal("Internal Error: pqid > Max_proc !");
if( pqid == -1 ) {
/* Check if there is something to wait for. */
int i;
for( i=0; i<Max_proc && !_procs[i].pr_valid; i++ )
;
if( i == Max_proc )
return(-1);
pid = -1;
waitchild = FALSE;
}
else {
/* Check if pqid is active. */
if( !_procs[pqid].pr_valid ) {
/* Make this an error? */
Warning("Internal Warning: pqid is not active!?");
return(-1);
}
pid = _procs[pqid].pr_pid;
waitchild = _procs[pqid].pr_wfc;
}
/* It is impossible that processes that were started from _exec_shell
* have follow-up commands in its process entry. Unset Is_exec_shell
* to prevent piping of child processes that are started from the
* _finished_child subroutine and reset to its original value when
* leaving this function. */
Is_exec_shell = FALSE;
do {
/* Wait for the next process to finish. */
if( (pid != -1) && (wid = waitpid(pid, &status, WNOHANG)) ) {
/* if wid is 0 this means that pid didn't finish yet. In this case
* just handle the next finished process in the following "else". */
;
}
else {
/* Here might be the culprit for the famous OOo build hang. If
* cygwin manages to "loose" a process and none else is left the
* wait() will wait forever. */
wid = wait(&status);
/* If we get an error tell the error handling routine below that we
* were not waiting for a specific pid. */
if( wid == -1 )
pid = -1;
}
/* If ECHILD is set from waitpid/wait then no child was left. */
if( wid == -1 ) {
if(errno != ECHILD) {
/* Wait was interrupted or a child was terminated (SIGCHLD) */
if ( in_quit() ) {
/* We're already terminating, just continue. */
return 0;
} else {
Fatal( "dmake was interrupted or a child terminated: %d : %s - stopping all childs ...", errno, strerror( errno ) );
}
} else {
if( pid != -1 ) {
/* If we know the pid disable the pq entry. */
if( _procs[pqid].pr_valid ) {
_procs[pqid].pr_valid = 0;
_procs[pqid].pr_recipe = NIL(RCP);
_proc_cnt--;
}
} else {
/* otherwise disable all remaining pq's. As we don't know
* which pid failed there is no gracefull way to terminate. */
int i;
for( i=0; i<Max_proc; i++ ) {
_procs[i].pr_valid = 0;
_procs[i].pr_recipe = NIL(RCP);
}
_proc_cnt = 0;
}
/* The pid we were waiting for or any of the remaining childs
* (pid == -1) is missing. This should not happen and means
* that the process got lost or was treated elsewhere. */
Fatal( "Internal Error: Child is missing but still listed in _procs[x] %d: %s\n"
"\nTemporary or .ERRREMOVE targets might not have been removed!\n",
errno, strerror( errno ) );
}
}
_abort_flg = abort_flg;
_finished_child(wid, status);
_abort_flg = FALSE;
if( waitchild ) {
/* If pid != wid the process we're waiting for might have been
* finished from a "Wait_for_child(FALSE, -1)" call from
* _finished_child() -> runargv(). */
if( pid != wid ) {
if( !_procs[pqid].pr_valid || _procs[pqid].pr_pid != pid ) {
/* Someone finished pid, no need to wait further. */
waitchild = FALSE;
}
}
else
/* We finished pid, no need to wait further. */
waitchild = FALSE;
}
}
while( waitchild );
Is_exec_shell = is_exec_shell_status;
return(0);
}
PUBLIC void
Clean_up_processes()
{
register int i;
int ret;
if( _procs != NIL(PR) ) {
for( i=0; i<Max_proc; i++ )
if( _procs[i].pr_valid ) {
if( (ret = kill(_procs[i].pr_pid, SIGTERM)) ) {
fprintf(stderr, "Killing of pid %d from pq[%d] failed with: %s - %d ret: %d\n",
_procs[i].pr_pid, i,
strerror(errno), SIGTERM, ret );
}
}
}
}
static int
_add_child( pid, target, ignore, last, wfc )/*
==============================================
Creates/amend a process queue entry and enters the child parameters.
The pid == -1 represents an internal command and the function returns
the used process array index. For non-internal commands the function
returns -1.
If wfc (wait for completion) is TRUE the function calls
Wait_for_child to wait for the whole process queue to be finished.
*/
int pid;
CELLPTR target;
int ignore;
int last;
int wfc;
{
register int i;
register PR *pp;
/* Never change MAXPROCESS after _procs is allocated. */
if( _procs_size != Max_proc ) {
/* If procs was never initialize this is OK, do it now. */
if( _procs == NIL(PR) ) {
_procs_size = Max_proc;
TALLOC( _procs, Max_proc, PR );
}
else {
Fatal( "MAXPROCESS changed from `%d' to `%d' after a command was executed!", _procs_size, Max_proc );
}
}
if( Measure & M_RECIPE )
Do_profile_output( "s", M_RECIPE, target );
/* If _use_i!=-1 then this function is called by _finished_child()
* ( through runargv() ). */
if( (i = _use_i) == -1 ) {
for( i=0; i<Max_proc; i++ )
if( !_procs[i].pr_valid )
break;
}
else {
/* Re-use the process queue number given by _use_i.
* Free the pointer before using it again below. */
FREE( _procs[i].pr_dir );
}
pp = _procs+i;
pp->pr_valid = 1;
pp->pr_pid = pid;
pp->pr_target = target;
pp->pr_ignore = ignore;
pp->pr_last = last;
pp->pr_wfc = wfc;
/* Freed above and after the last recipe in _finished child(). */
pp->pr_dir = DmStrDup(Get_current_dir());
Current_target = NIL(CELL);
_proc_cnt++;
if( pid != -1 ) {
/* Wait for each recipe to finish if wfc is TRUE. This
* basically forces sequential execution. */
if( wfc )
Wait_for_child( FALSE, i );
return -1;
} else
return i;
}
static void
_finished_child(cid, status)/*
==============================
Handle process array entry for finished child. This can be a finished
process or a finished internal command depending on the content of cid.
For cid >= 1 the value of cid is used as the pid to of the finished
process and for cid < 1 -cid is used as the process array index of the
internal command.
*/
int cid;
int status;
{
register int i;
char *dir;
if(cid < 1) {
/* internal command */
i = -cid;
}
else {
for( i=0; i<Max_proc; i++ )
if( _procs[i].pr_valid && _procs[i].pr_pid == cid )
break;
/* Some children we didn't make esp true if using /bin/sh to execute a
* a pipe and feed the output as a makefile into dmake. */
if( i == Max_proc ) {
Warning("Internal Warning: finished pid %d is not in pq!?", cid);
return;
}
}
/* Not a running process anymore, the next runargv() will not use
* _attach_cmd(). */
_procs[i].pr_valid = 0;
if( Measure & M_RECIPE )
Do_profile_output( "e", M_RECIPE, _procs[i].pr_target );
_proc_cnt--;
dir = DmStrDup(Get_current_dir());
Set_dir( _procs[i].pr_dir );
if( _procs[i].pr_recipe != NIL(RCP) && !_abort_flg ) {
RCPPTR rp = _procs[i].pr_recipe;
Current_target = _procs[i].pr_target;
Handle_result( status, _procs[i].pr_ignore, FALSE, _procs[i].pr_target );
Current_target = NIL(CELL);
if ( _procs[i].pr_target->ce_attr & A_ERROR ) {
_procs[i].pr_last = TRUE;
goto ABORT_REMAINDER_OF_RECIPE;
}
_procs[i].pr_recipe = rp->prp_next;
_use_i = i;
/* Run next recipe line. The rp->prp_attr propagates a possible
* wfc condition. */
runargv( _procs[i].pr_target, rp->prp_group,
rp->prp_last, rp->prp_attr, &rp->prp_cmd );
_use_i = -1;
FREE( rp->prp_cmd );
FREE( rp );
/* If all process queues are used wait for the next process to
* finish. Is this really needed here? */
if( _proc_cnt == Max_proc ) Wait_for_child( FALSE, -1 );
}
else {
/* empty the queue on abort. */
if( _abort_flg )
_procs[i].pr_recipe = NIL(RCP);
Handle_result(status,_procs[i].pr_ignore,_abort_flg,_procs[i].pr_target);
ABORT_REMAINDER_OF_RECIPE:
if( _procs[i].pr_last ) {
FREE(_procs[i].pr_dir ); /* Set in _add_child() */
if( !Doing_bang ) {
/* Update_time_stamp() triggers the deletion of intermediate
* targets. This starts a new process queue, so we have to
* clear the _use_i variable. */
int my_use_i = _use_i;
_use_i = -1;
Update_time_stamp( _procs[i].pr_target );
_use_i = my_use_i;
}
}
}
Set_dir(dir);
FREE(dir);
}
static int
_running( cp )/*
================
Check if target exists in process array AND is running. Return its
process array index if it is running, return -1 otherwise.
*/
CELLPTR cp;
{
register int i;
if( !_procs ) return( -1 );
for( i=0; i<Max_proc; i++ )
if( _procs[i].pr_valid &&
_procs[i].pr_target == cp )
break;
return( i == Max_proc ? -1 : i );
}
static void
_attach_cmd( cmd, group, cp, cmnd_attr, last )/*
================================================
Attach to an active process queue. Inherit wfc setting. */
char *cmd;
int group;
CELLPTR cp;
t_attr cmnd_attr;
int last;
{
register int i;
RCPPTR rp;
for( i=0; i<Max_proc; i++ )
if( _procs[i].pr_valid &&
_procs[i].pr_target == cp )
break;
TALLOC( rp, 1, RCP );
rp->prp_cmd = DmStrDup(cmd);
rp->prp_attr = cmnd_attr;
/* Inherit wfc from process queue. */
if( _procs[i].pr_wfc )
rp->prp_attr |= A_WFC;
rp->prp_group = group;
rp->prp_last = last;
if( _procs[i].pr_recipe == NIL(RCP) )
_procs[i].pr_recipe = _procs[i].pr_recipe_end = rp;
else {
_procs[i].pr_recipe_end->prp_next = rp;
_procs[i].pr_recipe_end = rp;
}
}
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