proc.c - fp2-dev/platform/external/ltrace - Gitiles

 #include "config.h"

 #if defined(HAVE_LIBUNWIND)
 #include <libunwind.h>
 #include <libunwind-ptrace.h>
 #endif /* defined(HAVE_LIBUNWIND) */

 #include <sys/types.h>
 #include <string.h>
 #include <stdio.h>
 #include <errno.h>
 #include <stdlib.h>
 #include <assert.h>
 #include <error.h>

 #include "common.h"
 #include "breakpoint.h"
 #include "proc.h"
 #include "filter.h"

 static int
 process_bare_init(struct Process *proc, const char *filename, pid_t pid)
 {
 	fprintf(stderr, "process_bare_init %s %d\n", filename, pid);
 	memset(proc, 0, sizeof(*proc));

 	proc->filename = strdup(filename);
 	if (proc->filename == NULL) {
 	fail:
 		free(proc->filename);
 		if (proc->breakpoints != NULL)
 			dict_clear(proc->breakpoints);
 		return -1;
 	}

 	/* Add process so that we know who the leader is.  */
 	proc->pid = pid;
 	add_process(proc);
 	if (proc->leader == NULL)
 		goto fail;

 	if (proc->leader == proc) {
 		proc->breakpoints = dict_init(dict_key2hash_int,
 					      dict_key_cmp_int);
 		if (proc->breakpoints == NULL)
 			goto fail;
 	} else {
 		proc->breakpoints = NULL;
 	}

 #if defined(HAVE_LIBUNWIND)
 	proc->unwind_priv = _UPT_create(pid);
 	proc->unwind_as = unw_create_addr_space(&_UPT_accessors, 0);
 #endif /* defined(HAVE_LIBUNWIND) */

 	return 0;
 }

 static void
 process_bare_destroy(struct Process *proc)
 {
 	free(proc->filename);
 	dict_clear(proc->breakpoints);
 	remove_process(proc);
 }

 int
 process_init(struct Process *proc, const char *filename, pid_t pid, int enable)
 {
 	fprintf(stderr, "process_init %s %d enable=%d\n", filename, pid, enable);
 	if (process_bare_init(proc, filename, pid) < 0) {
 		error(0, errno, "init process %d", pid);
 		return -1;
 	}

 	if (proc->leader == proc && breakpoints_init(proc, enable) < 0) {
 		fprintf(stderr, "failed to init breakpoints %d\n",
 			proc->pid);
 		process_bare_destroy(proc);
 		return -1;
 	}

 	return 0;
 }

 struct Process *
 open_program(const char *filename, pid_t pid, int enable)
 {
 	fprintf(stderr, "open_program %s %d enable=%d\n",
 		filename, pid, enable);
 	assert(pid != 0);
 	struct Process *proc = malloc(sizeof(*proc));
 	if (proc == NULL
 	    || process_init(proc, filename, pid, enable) < 0) {
 		free(proc);
 		return NULL;
 	}
 	return proc;
 }

 struct clone_single_bp_data {
 	struct Process *old_proc;
 	struct Process *new_proc;
 	int error;
 };

 struct find_symbol_data {
 	struct library_symbol *old_libsym;
 	struct library_symbol *found_libsym;
 };

 static enum callback_status
 find_sym_in_lib(struct Process *proc, struct library *lib, void *u)
 {
 	struct find_symbol_data *fs = u;
 	fs->found_libsym
 		= library_each_symbol(lib, NULL, library_symbol_equal_cb,
 				      fs->old_libsym);
 	return fs->found_libsym != NULL ? CBS_STOP : CBS_CONT;
 }

 static void
 clone_single_bp(void *key, void *value, void *u)
 {
 	target_address_t addr = (target_address_t)key;
 	struct breakpoint *bp = value;
 	struct clone_single_bp_data *data = u;

 	/* Find library and symbol that this symbol was linked to.  */
 	struct library_symbol *libsym = bp->libsym;
 	struct library *lib = NULL;
 	if (libsym != NULL) {
 		struct find_symbol_data f_data = {
 			.old_libsym = libsym,
 		};
 		lib = proc_each_library(data->old_proc, NULL,
 					find_sym_in_lib, &f_data);
 		assert(lib != NULL);
 		libsym = f_data.found_libsym;
 	}

 	/* LIB and LIBSYM now hold the new library and symbol that
 	 * correspond to the original breakpoint.  Now we can do the
 	 * clone itself.  */
 	struct breakpoint *clone = malloc(sizeof(*clone));
 	if (clone == NULL
 	    || breakpoint_init(clone, data->new_proc, addr, libsym) < 0) {
 		data->error = -1;
 		return;
 	}
 	breakpoint_set_callbacks(clone, bp->cbs);
 }

 int
 process_clone(struct Process *retp, struct Process *proc, pid_t pid)
 {
 	if (process_bare_init(retp, proc->filename, pid) < 0) {
 	fail:
 		error(0, errno, "clone process %d->%d", proc->pid, pid);
 		return -1;
 	}

 	/* For non-leader processes, that's all we need to do.  */
 	if (proc->leader != proc)
 		return 0;

 	/* Clone symbols first so that we can clone and relink
 	 * breakpoints.  */
 	struct library *lib;
 	struct library **nlibp = &retp->libraries;
 	for (lib = proc->libraries; lib != NULL; lib = lib->next) {
 		*nlibp = malloc(sizeof(**nlibp));
 		if (*nlibp == NULL
 		    || library_clone(*nlibp, lib) < 0) {
 		fail2:
 			process_bare_destroy(retp);

 			/* Error when cloning.  Unroll what was done.  */
 			for (lib = retp->libraries; lib != NULL; ) {
 				struct library *next = lib->next;
 				library_destroy(lib);
 				free(lib);
 				lib = next;
 			}
 			goto fail;
 		}

 		nlibp = &(*nlibp)->next;
 	}

 	/* Now clone breakpoints.  Symbol relinking is done in
 	 * clone_single_bp.  */
 	struct clone_single_bp_data data = {
 		.old_proc = proc,
 		.new_proc = retp,
 		.error = 0,
 	};
 	dict_apply_to_all(proc->breakpoints, &clone_single_bp, &data);

 	if (data.error < 0)
 		goto fail2;

 	return 0;
 }

 static int
 open_one_pid(pid_t pid)
 {
 	Process *proc;
 	char *filename;
 	debug(DEBUG_PROCESS, "open_one_pid(pid=%d)", pid);

 	/* Get the filename first.  Should the trace_pid fail, we can
 	 * easily free it, untracing is more work.  */
 	if ((filename = pid2name(pid)) == NULL
 	    || trace_pid(pid) < 0) {
 		free(filename);
 		return -1;
 	}

 	proc = open_program(filename, pid, 0);
 	if (proc == NULL)
 		return -1;
 	trace_set_options(proc, pid);

 	return 0;
 }

 static enum callback_status
 start_one_pid(Process * proc, void * data)
 {
 	continue_process(proc->pid);
 	return CBS_CONT;
 }

 void
 open_pid(pid_t pid)
 {
 	debug(DEBUG_PROCESS, "open_pid(pid=%d)", pid);
 	/* If we are already tracing this guy, we should be seeing all
 	 * his children via normal tracing route.  */
 	if (pid2proc(pid) != NULL)
 		return;

 	/* First, see if we can attach the requested PID itself.  */
 	if (open_one_pid(pid)) {
 		fprintf(stderr, "Cannot attach to pid %u: %s\n",
 			pid, strerror(errno));
 		trace_fail_warning(pid);
 		return;
 	}

 	/* Now attach to all tasks that belong to that PID.  There's a
 	 * race between process_tasks and open_one_pid.  So when we
 	 * fail in open_one_pid below, we just do another round.
 	 * Chances are that by then that PID will have gone away, and
 	 * that's why we have seen the failure.  The processes that we
 	 * manage to open_one_pid are stopped, so we should eventually
 	 * reach a point where process_tasks doesn't give any new
 	 * processes (because there's nobody left to produce
 	 * them).  */
 	size_t old_ntasks = 0;
 	int have_all;
 	while (1) {
 		pid_t *tasks;
 		size_t ntasks;
 		size_t i;

 		if (process_tasks(pid, &tasks, &ntasks) < 0) {
 			fprintf(stderr, "Cannot obtain tasks of pid %u: %s\n",
 				pid, strerror(errno));
 			break;
 		}

 		have_all = 1;
 		for (i = 0; i < ntasks; ++i)
 			if (pid2proc(tasks[i]) == NULL
 			    && open_one_pid(tasks[i]))
 				have_all = 0;

 		free(tasks);

 		if (have_all && old_ntasks == ntasks)
 			break;
 		old_ntasks = ntasks;
 	}

 	/* Done.  Now initialize breakpoints and then continue
 	 * everyone.  */
 	Process * leader;
 	leader = pid2proc(pid)->leader;
 	enable_all_breakpoints(leader);

 	each_task(pid2proc(pid)->leader, NULL, start_one_pid, NULL);
 }

 static enum callback_status
 find_proc(Process * proc, void * data)
 {
 	pid_t pid = (pid_t)(uintptr_t)data;
 	return proc->pid == pid ? CBS_STOP : CBS_CONT;
 }

 Process *
 pid2proc(pid_t pid) {
 	return each_process(NULL, &find_proc, (void *)(uintptr_t)pid);
 }

 static Process * list_of_processes = NULL;

 static void
 unlist_process(Process * proc)
 {
 	Process *tmp;

 	if (list_of_processes == proc) {
 		list_of_processes = list_of_processes->next;
 		return;
 	}

 	for (tmp = list_of_processes; ; tmp = tmp->next) {
 		/* If the following assert fails, the process wasn't
 		 * in the list.  */
 		assert(tmp->next != NULL);

 		if (tmp->next == proc) {
 			tmp->next = tmp->next->next;
 			return;
 		}
 	}
 }

 struct Process *
 each_process(struct Process *start_after,
 	     enum callback_status(*cb)(struct Process *proc, void *data),
 	     void *data)
 {
 	struct Process *it = start_after == NULL ? list_of_processes
 		: start_after->next;

 	while (it != NULL) {
 		/* Callback might call remove_process.  */
 		struct Process *next = it->next;
 		switch ((*cb)(it, data)) {
 		case CBS_FAIL:
 			/* XXX handle me */
 		case CBS_STOP:
 			return it;
 		case CBS_CONT:
 			break;
 		}
 		it = next;
 	}
 	return NULL;
 }

 Process *
 each_task(struct Process *proc, struct Process *start_after,
 	  enum callback_status(*cb)(struct Process *proc, void *data),
 	  void *data)
 {
 	assert(proc != NULL);
 	struct Process *it = start_after == NULL ? proc->leader
 		: start_after->next;

 	if (it != NULL) {
 		struct Process *leader = it->leader;
 		while (it != NULL && it->leader == leader) {
 			/* Callback might call remove_process.  */
 			struct Process *next = it->next;
 			switch ((*cb)(it, data)) {
 			case CBS_FAIL:
 				/* XXX handle me */
 			case CBS_STOP:
 				return it;
 			case CBS_CONT:
 				break;
 			}
 			it = next;
 		}
 	}
 	return NULL;
 }

 void
 add_process(Process * proc)
 {
 	fprintf(stderr, "add_process %d\n", proc->pid);
 	Process ** leaderp = &list_of_processes;
 	if (proc->pid) {
 		pid_t tgid = process_leader(proc->pid);
 		fprintf(stderr, " + leader is %d\n", tgid);
 		if (tgid == 0)
 			/* Must have been terminated before we managed
 			 * to fully attach.  */
 			return;
 		if (tgid == proc->pid)
 			proc->leader = proc;
 		else {
 			Process * leader = pid2proc(tgid);
 			proc->leader = leader;
 			if (leader != NULL)
 				leaderp = &leader->next;
 		}
 	}
 	proc->next = *leaderp;
 	*leaderp = proc;
 }

 void
 change_process_leader(Process * proc, Process * leader)
 {
 	Process ** leaderp = &list_of_processes;
 	if (proc->leader == leader)
 		return;

 	assert(leader != NULL);
 	unlist_process(proc);
 	if (proc != leader)
 		leaderp = &leader->next;

 	proc->leader = leader;
 	proc->next = *leaderp;
 	*leaderp = proc;
 }

 static enum callback_status
 clear_leader(struct Process *proc, void *data)
 {
 	debug(DEBUG_FUNCTION, "detach_task %d from leader %d",
 	      proc->pid, proc->leader->pid);
 	proc->leader = NULL;
 	return CBS_CONT;
 }

 static enum ecb_status
 event_for_proc(Event * event, void * data)
 {
 	if (event->proc == data)
 		return ecb_deque;
 	else
 		return ecb_cont;
 }

 static void
 delete_events_for(Process * proc)
 {
 	Event * event;
 	while ((event = each_qd_event(&event_for_proc, proc)) != NULL)
 		free(event);
 }

 void
 remove_process(Process *proc)
 {
 	debug(DEBUG_FUNCTION, "remove_proc(pid=%d)", proc->pid);

 	if (proc->leader == proc)
 		each_task(proc, NULL, &clear_leader, NULL);

 	unlist_process(proc);
 	delete_events_for(proc);
 }

 void
 install_event_handler(Process *proc, struct event_handler *handler)
 {
 	debug(DEBUG_FUNCTION, "install_event_handler(pid=%d, %p)", proc->pid, handler);
 	assert(proc->event_handler == NULL);
 	proc->event_handler = handler;
 }

 void
 destroy_event_handler(Process * proc)
 {
 	struct event_handler *handler = proc->event_handler;
 	debug(DEBUG_FUNCTION, "destroy_event_handler(pid=%d, %p)", proc->pid, handler);
 	assert(handler != NULL);
 	if (handler->destroy != NULL)
 		handler->destroy(handler);
 	free(handler);
 	proc->event_handler = NULL;
 }

 static enum callback_status
 breakpoint_for_symbol(struct library_symbol *libsym, void *data)
 {
 	struct Process *proc = data;

 	if (!filter_matches_symbol(options.filter, libsym))
 		return CBS_CONT;

 	struct breakpoint *bp = malloc(sizeof(*bp));
 	if (bp == NULL
 	    || breakpoint_init(bp, proc, libsym->enter_addr, libsym) < 0) {
 	fail:
 		free(bp);
 		return CBS_FAIL;
 	}
 	if (proc_add_breakpoint(proc, bp) < 0) {
 		breakpoint_destroy(bp);
 		goto fail;
 	}

 	/* If this is dlopened library, turn on the breakpoint right
 	 * away.  */
 	if (proc->fixed_libs != NULL
 	    && breakpoint_turn_on(bp) < 0) {
 		proc_remove_breakpoint(proc, bp);
 		breakpoint_destroy(bp);
 		goto fail;
 	}

 	return CBS_CONT;
 }

 void
 proc_add_library(struct Process *proc, struct library *lib)
 {
 	assert(lib->next == NULL);
 	lib->next = proc->libraries;
 	proc->libraries = lib;
 	fprintf(stderr, "=== Added library %s@%p (%s) to %d:\n",
 		lib->soname, lib->base, lib->pathname, proc->pid);

 	if (!filter_matches_library(options.filter, lib))
 		return;

 	struct library_symbol *libsym = NULL;
 	while ((libsym = library_each_symbol(lib, libsym, breakpoint_for_symbol,
 					     proc)) != NULL)
 		error(0, errno, "insert breakpoint for %s", libsym->name);
 }

 int
 proc_remove_library(struct Process *proc, struct library *lib)
 {
 	struct library **libp;
 	for (libp = &proc->libraries; *libp != NULL; libp = &(*libp)->next)
 		if (*libp == lib) {
 			*libp = lib->next;
 			return 0;
 		}
 	return -1;
 }

 struct library *
 proc_each_library(struct Process *proc, struct library *it,
 		  enum callback_status (*cb)(struct Process *proc,
 					     struct library *lib, void *data),
 		  void *data)
 {
 	if (it == NULL)
 		it = proc->libraries;

 	while (it != NULL) {
 		struct library *next = it->next;

 		switch (cb(proc, it, data)) {
 		case CBS_FAIL:
 			/* XXX handle me */
 		case CBS_STOP:
 			return it;
 		case CBS_CONT:
 			break;
 		}

 		it = next;
 	}

 	return NULL;
 }

 int
 proc_add_breakpoint(struct Process *proc, struct breakpoint *bp)
 {
 	struct Process *leader = proc->leader;

 	/* Only the group leader should be getting the breakpoints and
 	 * thus have ->breakpoint initialized.  */
 	assert(leader != NULL);
 	assert(leader->breakpoints != NULL);

 	/* Make sure it wasn't inserted yet.  */
 	assert(bp->proc == NULL);

 	debug(DEBUG_FUNCTION, "proc_insert_breakpoint(pid=%d, %s@%p)",
 	      proc->pid, breakpoint_name(bp), bp->addr);

 	assert(dict_find_entry(leader->breakpoints, bp->addr) == NULL);
 	if (dict_enter(leader->breakpoints, bp->addr, bp) < 0) {
 		error(0, errno, "couldn't enter breakpoint %s@%p to dictionary",
 		      breakpoint_name(bp), bp->addr);
 		return -1;
 	}

 	bp->proc = proc;
 	return 0;
 }

 int
 proc_remove_breakpoint(struct Process *proc, struct breakpoint *bp)
 {
 	/* XXX We can't, really.  We are missing dict_remove.  */
 	assert(!"Not yet implemented!");
 	abort();
 }
	#include "config.h"

	#if defined(HAVE_LIBUNWIND)
	#include <libunwind.h>
	#include <libunwind-ptrace.h>
	#endif /* defined(HAVE_LIBUNWIND) */

	#include <sys/types.h>
	#include <string.h>
	#include <stdio.h>
	#include <errno.h>
	#include <stdlib.h>
	#include <assert.h>
	#include <error.h>

	#include "common.h"
	#include "breakpoint.h"
	#include "proc.h"
	#include "filter.h"

	static int
	process_bare_init(struct Process proc, const char filename, pid_t pid)
	{
	fprintf(stderr, "process_bare_init %s %d\n", filename, pid);
	memset(proc, 0, sizeof(*proc));

	proc->filename = strdup(filename);
	if (proc->filename == NULL) {
	fail:
	free(proc->filename);
	if (proc->breakpoints != NULL)
	dict_clear(proc->breakpoints);
	return -1;
	}

	/* Add process so that we know who the leader is. */
	proc->pid = pid;
	add_process(proc);
	if (proc->leader == NULL)
	goto fail;

	if (proc->leader == proc) {
	proc->breakpoints = dict_init(dict_key2hash_int,
	dict_key_cmp_int);
	if (proc->breakpoints == NULL)
	goto fail;
	} else {
	proc->breakpoints = NULL;
	}

	#if defined(HAVE_LIBUNWIND)
	proc->unwind_priv = _UPT_create(pid);
	proc->unwind_as = unw_create_addr_space(&_UPT_accessors, 0);
	#endif /* defined(HAVE_LIBUNWIND) */

	return 0;
	}

	static void
	process_bare_destroy(struct Process *proc)
	{
	free(proc->filename);
	dict_clear(proc->breakpoints);
	remove_process(proc);
	}

	int
	process_init(struct Process proc, const char filename, pid_t pid, int enable)
	{
	fprintf(stderr, "process_init %s %d enable=%d\n", filename, pid, enable);
	if (process_bare_init(proc, filename, pid) < 0) {
	error(0, errno, "init process %d", pid);
	return -1;
	}

	if (proc->leader == proc && breakpoints_init(proc, enable) < 0) {
	fprintf(stderr, "failed to init breakpoints %d\n",
	proc->pid);
	process_bare_destroy(proc);
	return -1;
	}

	return 0;
	}

	struct Process *
	open_program(const char *filename, pid_t pid, int enable)
	{
	fprintf(stderr, "open_program %s %d enable=%d\n",
	filename, pid, enable);
	assert(pid != 0);
	struct Process proc = malloc(sizeof(proc));
	if (proc == NULL
	\|\| process_init(proc, filename, pid, enable) < 0) {
	free(proc);
	return NULL;
	}
	return proc;
	}

	struct clone_single_bp_data {
	struct Process *old_proc;
	struct Process *new_proc;
	int error;
	};

	struct find_symbol_data {
	struct library_symbol *old_libsym;
	struct library_symbol *found_libsym;
	};

	static enum callback_status
	find_sym_in_lib(struct Process proc, struct library lib, void *u)
	{
	struct find_symbol_data *fs = u;
	fs->found_libsym
	= library_each_symbol(lib, NULL, library_symbol_equal_cb,
	fs->old_libsym);
	return fs->found_libsym != NULL ? CBS_STOP : CBS_CONT;
	}

	static void
	clone_single_bp(void key, void value, void *u)
	{
	target_address_t addr = (target_address_t)key;
	struct breakpoint *bp = value;
	struct clone_single_bp_data *data = u;

	/* Find library and symbol that this symbol was linked to. */
	struct library_symbol *libsym = bp->libsym;
	struct library *lib = NULL;
	if (libsym != NULL) {
	struct find_symbol_data f_data = {
	.old_libsym = libsym,
	};
	lib = proc_each_library(data->old_proc, NULL,
	find_sym_in_lib, &f_data);
	assert(lib != NULL);
	libsym = f_data.found_libsym;
	}

	/* LIB and LIBSYM now hold the new library and symbol that
	* correspond to the original breakpoint. Now we can do the
	* clone itself. */
	struct breakpoint clone = malloc(sizeof(clone));
	if (clone == NULL
	\|\| breakpoint_init(clone, data->new_proc, addr, libsym) < 0) {
	data->error = -1;
	return;
	}
	breakpoint_set_callbacks(clone, bp->cbs);
	}

	int
	process_clone(struct Process retp, struct Process proc, pid_t pid)
	{
	if (process_bare_init(retp, proc->filename, pid) < 0) {
	fail:
	error(0, errno, "clone process %d->%d", proc->pid, pid);
	return -1;
	}

	/* For non-leader processes, that's all we need to do. */
	if (proc->leader != proc)
	return 0;

	/* Clone symbols first so that we can clone and relink
	* breakpoints. */
	struct library *lib;
	struct library **nlibp = &retp->libraries;
	for (lib = proc->libraries; lib != NULL; lib = lib->next) {
	nlibp = malloc(sizeof(*nlibp));
	if (*nlibp == NULL
	\|\| library_clone(*nlibp, lib) < 0) {
	fail2:
	process_bare_destroy(retp);

	/* Error when cloning. Unroll what was done. */
	for (lib = retp->libraries; lib != NULL; ) {
	struct library *next = lib->next;
	library_destroy(lib);
	free(lib);
	lib = next;
	}
	goto fail;
	}

	nlibp = &(*nlibp)->next;
	}

	/* Now clone breakpoints. Symbol relinking is done in
	* clone_single_bp. */
	struct clone_single_bp_data data = {
	.old_proc = proc,
	.new_proc = retp,
	.error = 0,
	};
	dict_apply_to_all(proc->breakpoints, &clone_single_bp, &data);

	if (data.error < 0)
	goto fail2;

	return 0;
	}

	static int
	open_one_pid(pid_t pid)
	{
	Process *proc;
	char *filename;
	debug(DEBUG_PROCESS, "open_one_pid(pid=%d)", pid);

	/* Get the filename first. Should the trace_pid fail, we can
	* easily free it, untracing is more work. */
	if ((filename = pid2name(pid)) == NULL
	\|\| trace_pid(pid) < 0) {
	free(filename);
	return -1;
	}

	proc = open_program(filename, pid, 0);
	if (proc == NULL)
	return -1;
	trace_set_options(proc, pid);

	return 0;
	}

	static enum callback_status
	start_one_pid(Process * proc, void * data)
	{
	continue_process(proc->pid);
	return CBS_CONT;
	}

	void
	open_pid(pid_t pid)
	{
	debug(DEBUG_PROCESS, "open_pid(pid=%d)", pid);
	/* If we are already tracing this guy, we should be seeing all
	* his children via normal tracing route. */
	if (pid2proc(pid) != NULL)
	return;

	/* First, see if we can attach the requested PID itself. */
	if (open_one_pid(pid)) {
	fprintf(stderr, "Cannot attach to pid %u: %s\n",
	pid, strerror(errno));
	trace_fail_warning(pid);
	return;
	}

	/* Now attach to all tasks that belong to that PID. There's a
	* race between process_tasks and open_one_pid. So when we
	* fail in open_one_pid below, we just do another round.
	* Chances are that by then that PID will have gone away, and
	* that's why we have seen the failure. The processes that we
	* manage to open_one_pid are stopped, so we should eventually
	* reach a point where process_tasks doesn't give any new
	* processes (because there's nobody left to produce
	* them). */
	size_t old_ntasks = 0;
	int have_all;
	while (1) {
	pid_t *tasks;
	size_t ntasks;
	size_t i;

	if (process_tasks(pid, &tasks, &ntasks) < 0) {
	fprintf(stderr, "Cannot obtain tasks of pid %u: %s\n",
	pid, strerror(errno));
	break;
	}

	have_all = 1;
	for (i = 0; i < ntasks; ++i)
	if (pid2proc(tasks[i]) == NULL
	&& open_one_pid(tasks[i]))
	have_all = 0;

	free(tasks);

	if (have_all && old_ntasks == ntasks)
	break;
	old_ntasks = ntasks;
	}

	/* Done. Now initialize breakpoints and then continue
	* everyone. */
	Process * leader;
	leader = pid2proc(pid)->leader;
	enable_all_breakpoints(leader);

	each_task(pid2proc(pid)->leader, NULL, start_one_pid, NULL);
	}

	static enum callback_status
	find_proc(Process * proc, void * data)
	{
	pid_t pid = (pid_t)(uintptr_t)data;
	return proc->pid == pid ? CBS_STOP : CBS_CONT;
	}

	Process *
	pid2proc(pid_t pid) {
	return each_process(NULL, &find_proc, (void *)(uintptr_t)pid);
	}

	static Process * list_of_processes = NULL;

	static void
	unlist_process(Process * proc)
	{
	Process *tmp;

	if (list_of_processes == proc) {
	list_of_processes = list_of_processes->next;
	return;
	}

	for (tmp = list_of_processes; ; tmp = tmp->next) {
	/* If the following assert fails, the process wasn't
	* in the list. */
	assert(tmp->next != NULL);

	if (tmp->next == proc) {
	tmp->next = tmp->next->next;
	return;
	}
	}
	}

	struct Process *
	each_process(struct Process *start_after,
	enum callback_status(cb)(struct Process proc, void *data),
	void *data)
	{
	struct Process *it = start_after == NULL ? list_of_processes
	: start_after->next;

	while (it != NULL) {
	/* Callback might call remove_process. */
	struct Process *next = it->next;
	switch ((*cb)(it, data)) {
	case CBS_FAIL:
	/* XXX handle me */
	case CBS_STOP:
	return it;
	case CBS_CONT:
	break;
	}
	it = next;
	}
	return NULL;
	}

	Process *
	each_task(struct Process proc, struct Process start_after,
	enum callback_status(cb)(struct Process proc, void *data),
	void *data)
	{
	assert(proc != NULL);
	struct Process *it = start_after == NULL ? proc->leader
	: start_after->next;

	if (it != NULL) {
	struct Process *leader = it->leader;
	while (it != NULL && it->leader == leader) {
	/* Callback might call remove_process. */
	struct Process *next = it->next;
	switch ((*cb)(it, data)) {
	case CBS_FAIL:
	/* XXX handle me */
	case CBS_STOP:
	return it;
	case CBS_CONT:
	break;
	}
	it = next;
	}
	}
	return NULL;
	}

	void
	add_process(Process * proc)
	{
	fprintf(stderr, "add_process %d\n", proc->pid);
	Process ** leaderp = &list_of_processes;
	if (proc->pid) {
	pid_t tgid = process_leader(proc->pid);
	fprintf(stderr, " + leader is %d\n", tgid);
	if (tgid == 0)
	/* Must have been terminated before we managed
	* to fully attach. */
	return;
	if (tgid == proc->pid)
	proc->leader = proc;
	else {
	Process * leader = pid2proc(tgid);
	proc->leader = leader;
	if (leader != NULL)
	leaderp = &leader->next;
	}
	}
	proc->next = *leaderp;
	*leaderp = proc;
	}

	void
	change_process_leader(Process * proc, Process * leader)
	{
	Process ** leaderp = &list_of_processes;
	if (proc->leader == leader)
	return;

	assert(leader != NULL);
	unlist_process(proc);
	if (proc != leader)
	leaderp = &leader->next;

	proc->leader = leader;
	proc->next = *leaderp;
	*leaderp = proc;
	}

	static enum callback_status
	clear_leader(struct Process proc, void data)
	{
	debug(DEBUG_FUNCTION, "detach_task %d from leader %d",
	proc->pid, proc->leader->pid);
	proc->leader = NULL;
	return CBS_CONT;
	}

	static enum ecb_status
	event_for_proc(Event * event, void * data)
	{
	if (event->proc == data)
	return ecb_deque;
	else
	return ecb_cont;
	}

	static void
	delete_events_for(Process * proc)
	{
	Event * event;
	while ((event = each_qd_event(&event_for_proc, proc)) != NULL)
	free(event);
	}

	void
	remove_process(Process *proc)
	{
	debug(DEBUG_FUNCTION, "remove_proc(pid=%d)", proc->pid);

	if (proc->leader == proc)
	each_task(proc, NULL, &clear_leader, NULL);

	unlist_process(proc);
	delete_events_for(proc);
	}

	void
	install_event_handler(Process proc, struct event_handler handler)
	{
	debug(DEBUG_FUNCTION, "install_event_handler(pid=%d, %p)", proc->pid, handler);
	assert(proc->event_handler == NULL);
	proc->event_handler = handler;
	}

	void
	destroy_event_handler(Process * proc)
	{
	struct event_handler *handler = proc->event_handler;
	debug(DEBUG_FUNCTION, "destroy_event_handler(pid=%d, %p)", proc->pid, handler);
	assert(handler != NULL);
	if (handler->destroy != NULL)
	handler->destroy(handler);
	free(handler);
	proc->event_handler = NULL;
	}

	static enum callback_status
	breakpoint_for_symbol(struct library_symbol libsym, void data)
	{
	struct Process *proc = data;

	if (!filter_matches_symbol(options.filter, libsym))
	return CBS_CONT;

	struct breakpoint bp = malloc(sizeof(bp));
	if (bp == NULL
	\|\| breakpoint_init(bp, proc, libsym->enter_addr, libsym) < 0) {
	fail:
	free(bp);
	return CBS_FAIL;
	}
	if (proc_add_breakpoint(proc, bp) < 0) {
	breakpoint_destroy(bp);
	goto fail;
	}

	/* If this is dlopened library, turn on the breakpoint right
	* away. */
	if (proc->fixed_libs != NULL
	&& breakpoint_turn_on(bp) < 0) {
	proc_remove_breakpoint(proc, bp);
	breakpoint_destroy(bp);
	goto fail;
	}

	return CBS_CONT;
	}

	void
	proc_add_library(struct Process proc, struct library lib)
	{
	assert(lib->next == NULL);
	lib->next = proc->libraries;
	proc->libraries = lib;
	fprintf(stderr, "=== Added library %s@%p (%s) to %d:\n",
	lib->soname, lib->base, lib->pathname, proc->pid);

	if (!filter_matches_library(options.filter, lib))
	return;

	struct library_symbol *libsym = NULL;
	while ((libsym = library_each_symbol(lib, libsym, breakpoint_for_symbol,
	proc)) != NULL)
	error(0, errno, "insert breakpoint for %s", libsym->name);
	}

	int
	proc_remove_library(struct Process proc, struct library lib)
	{
	struct library **libp;
	for (libp = &proc->libraries; libp != NULL; libp = &(libp)->next)
	if (*libp == lib) {
	*libp = lib->next;
	return 0;
	}
	return -1;
	}

	struct library *
	proc_each_library(struct Process proc, struct library it,
	enum callback_status (cb)(struct Process proc,
	struct library lib, void data),
	void *data)
	{
	if (it == NULL)
	it = proc->libraries;

	while (it != NULL) {
	struct library *next = it->next;

	switch (cb(proc, it, data)) {
	case CBS_FAIL:
	/* XXX handle me */
	case CBS_STOP:
	return it;
	case CBS_CONT:
	break;
	}

	it = next;
	}

	return NULL;
	}

	int
	proc_add_breakpoint(struct Process proc, struct breakpoint bp)
	{
	struct Process *leader = proc->leader;

	/* Only the group leader should be getting the breakpoints and
	* thus have ->breakpoint initialized. */
	assert(leader != NULL);
	assert(leader->breakpoints != NULL);

	/* Make sure it wasn't inserted yet. */
	assert(bp->proc == NULL);

	debug(DEBUG_FUNCTION, "proc_insert_breakpoint(pid=%d, %s@%p)",
	proc->pid, breakpoint_name(bp), bp->addr);

	assert(dict_find_entry(leader->breakpoints, bp->addr) == NULL);
	if (dict_enter(leader->breakpoints, bp->addr, bp) < 0) {
	error(0, errno, "couldn't enter breakpoint %s@%p to dictionary",
	breakpoint_name(bp), bp->addr);
	return -1;
	}

	bp->proc = proc;
	return 0;
	}

	int
	proc_remove_breakpoint(struct Process proc, struct breakpoint bp)
	{
	/* XXX We can't, really. We are missing dict_remove. */
	assert(!"Not yet implemented!");
	abort();
	}