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/*

 * Copyright (c) 2008 Jiri Svoboda

 * All rights reserved.

 *

 * Redistribution and use in source and binary forms, with or without

 * modification, are permitted provided that the following conditions

 * are met:

 *

 * - Redistributions of source code must retain the above copyright

 *   notice, this list of conditions and the following disclaimer.

 * - 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.

 * - The name of the author may not be used to endorse or promote products

 *   derived from this software without specific prior written permission.

 *

 * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 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.

 */

/** @addtogroup generic

 * @{

 */

/**

 * @file

 * @brief	Udebug hooks and data structure management.

 *

 * Udebug is an interface that makes userspace debuggers possible.

 */

#include <synch/waitq.h>

#include <debug.h>

#include <udebug/udebug.h>

#include <errno.h>

#include <arch.h>

/** Initialize udebug part of task structure.

 *

 * Called as part of task structure initialization.

 * @param ut	Pointer to the structure to initialize.

 */

void udebug_task_init(udebug_task_t *ut)

{

	mutex_initialize(&ut->lock, MUTEX_PASSIVE);

	ut->dt_state = UDEBUG_TS_INACTIVE;

	ut->begin_call = NULL;

	ut->not_stoppable_count = 0;

	ut->evmask = 0;

}

/** Initialize udebug part of thread structure.

 *

 * Called as part of thread structure initialization.

 * @param ut	Pointer to the structure to initialize.

 */

void udebug_thread_initialize(udebug_thread_t *ut)

{

	mutex_initialize(&ut->lock, MUTEX_PASSIVE);

	waitq_initialize(&ut->go_wq);

	ut->go_call = NULL;

	ut->uspace_state = NULL;

	ut->go = false;

	ut->stoppable = true;

	ut->debug_active = false;

	ut->cur_event = 0; /* none */

}

/** Wait for a GO message.

 *

 * When a debugging event occurs in a thread or the thread is stopped,

 * this function is called to block the thread until a GO message

 * is received.

 *

 * @param wq	The wait queue used by the thread to wait for GO messages.

 */

static void udebug_wait_for_go(waitq_t *wq)

{

	int rc;

	ipl_t ipl;

	ipl = waitq_sleep_prepare(wq);

	wq->missed_wakeups = 0;	/* Enforce blocking. */

	rc = waitq_sleep_timeout_unsafe(wq, SYNCH_NO_TIMEOUT, SYNCH_FLAGS_NONE);

	waitq_sleep_finish(wq, rc, ipl);

}

/** Do a preliminary check that a debugging session is in progress.

 * 

 * This only requires the THREAD->udebug.lock mutex (and not TASK->udebug.lock

 * mutex). For an undebugged task, this will never block (while there could be

 * collisions by different threads on the TASK mutex), thus improving SMP

 * perormance for undebugged tasks.

 *

 * @return	True if the thread was in a debugging session when the function

 *		checked, false otherwise.

 */

static bool udebug_thread_precheck(void)

{

	bool res;

	mutex_lock(&THREAD->udebug.lock);

	res = THREAD->udebug.debug_active;

	mutex_unlock(&THREAD->udebug.lock);

	return res;

}

/** Start of stoppable section.

 *

 * A stoppable section is a section of code where if the thread can be stoped. In other words,

 * if a STOP operation is issued, the thread is guaranteed not to execute

 * any userspace instructions until the thread is resumed.

 *

 * Having stoppable sections is better than having stopping points, since

 * a thread can be stopped even when it is blocked indefinitely in a system

 * call (whereas it would not reach any stopping point).

 */

void udebug_stoppable_begin(void)

{

	int nsc;

	call_t *db_call, *go_call;

	ASSERT(THREAD);

	ASSERT(TASK);

	/* Early check for undebugged tasks */

	if (!udebug_thread_precheck()) {

		return;

	}

	mutex_lock(&TASK->udebug.lock);

	nsc = --TASK->udebug.not_stoppable_count;

	/* Lock order OK, THREAD->udebug.lock is after TASK->udebug.lock */

	mutex_lock(&THREAD->udebug.lock);

	ASSERT(THREAD->udebug.stoppable == false);

	THREAD->udebug.stoppable = true;

	if (TASK->udebug.dt_state == UDEBUG_TS_BEGINNING && nsc == 0) {

		/*

		 * This was the last non-stoppable thread. Reply to

		 * DEBUG_BEGIN call.

		 */

		db_call = TASK->udebug.begin_call;

		ASSERT(db_call);

		TASK->udebug.dt_state = UDEBUG_TS_ACTIVE;

		TASK->udebug.begin_call = NULL;

		IPC_SET_RETVAL(db_call->data, 0);

		ipc_answer(&TASK->answerbox, db_call);		

	} else if (TASK->udebug.dt_state == UDEBUG_TS_ACTIVE) {

		/*

		 * Active debugging session

		 */

		if (THREAD->udebug.debug_active == true &&

		    THREAD->udebug.go == false) {

			/*

			 * Thread was requested to stop - answer go call

			 */

			/* Make sure nobody takes this call away from us */

			go_call = THREAD->udebug.go_call;

			THREAD->udebug.go_call = NULL;

			ASSERT(go_call);

			IPC_SET_RETVAL(go_call->data, 0);

			IPC_SET_ARG1(go_call->data, UDEBUG_EVENT_STOP);

			THREAD->udebug.cur_event = UDEBUG_EVENT_STOP;

	    		ipc_answer(&TASK->answerbox, go_call);

		}

	}

	mutex_unlock(&THREAD->udebug.lock);

        mutex_unlock(&TASK->udebug.lock);

}

/** End of a stoppable section.

 *

 * This is the point where the thread will block if it is stopped.

 * (As, by definition, a stopped thread must not leave its stoppable section).

 */

void udebug_stoppable_end(void)

{

	/* Early check for undebugged tasks */

	if (!udebug_thread_precheck()) {

		return;

	}

restart:

	mutex_lock(&TASK->udebug.lock);

	mutex_lock(&THREAD->udebug.lock);

	if (THREAD->udebug.debug_active &&

	    THREAD->udebug.go == false) {

		TASK->udebug.begin_call = NULL;

		mutex_unlock(&THREAD->udebug.lock);

		mutex_unlock(&TASK->udebug.lock);

		udebug_wait_for_go(&THREAD->udebug.go_wq);

		goto restart;

		/* Must try again - have to lose stoppability atomically. */

	} else {

		++TASK->udebug.not_stoppable_count;

		ASSERT(THREAD->udebug.stoppable == true);

		THREAD->udebug.stoppable = false;

		mutex_unlock(&THREAD->udebug.lock);

		mutex_unlock(&TASK->udebug.lock);

	}

}

/** Upon being scheduled to run, check if the current thread should stop.

 *

 * This function is called from clock().

 */

void udebug_before_thread_runs(void)

{

	/* Check if we're supposed to stop */

	udebug_stoppable_begin();

	udebug_stoppable_end();

}

/** Syscall event hook.

 *

 * Must be called before and after servicing a system call. This generates

 * a SYSCALL_B or SYSCALL_E event, depending on the value of @a end_variant.

 */

void udebug_syscall_event(unative_t a1, unative_t a2, unative_t a3,

    unative_t a4, unative_t a5, unative_t a6, unative_t id, unative_t rc,

    bool end_variant)

{

	call_t *call;

	udebug_event_t etype;

	etype = end_variant ? UDEBUG_EVENT_SYSCALL_E : UDEBUG_EVENT_SYSCALL_B;

	/* Early check for undebugged tasks */

	if (!udebug_thread_precheck()) {

		return;

	}

	mutex_lock(&TASK->udebug.lock);

	mutex_lock(&THREAD->udebug.lock);

	/* Must only generate events when in debugging session and is go. */

	if (THREAD->udebug.debug_active != true ||

	    THREAD->udebug.go == false ||

	    (TASK->udebug.evmask & UDEBUG_EVMASK(etype)) == 0) {

		mutex_unlock(&THREAD->udebug.lock);

		mutex_unlock(&TASK->udebug.lock);

		return;

	}

	//printf("udebug_syscall_event\n");

	call = THREAD->udebug.go_call;

	THREAD->udebug.go_call = NULL;

	IPC_SET_RETVAL(call->data, 0);

	IPC_SET_ARG1(call->data, etype);

	IPC_SET_ARG2(call->data, id);

	IPC_SET_ARG3(call->data, rc);

	//printf("udebug_syscall_event/ipc_answer\n");

	THREAD->udebug.syscall_args[0] = a1;

	THREAD->udebug.syscall_args[1] = a2;

	THREAD->udebug.syscall_args[2] = a3;

	THREAD->udebug.syscall_args[3] = a4;

	THREAD->udebug.syscall_args[4] = a5;

	THREAD->udebug.syscall_args[5] = a6;

	/*

	 * Make sure udebug.go is false when going to sleep

	 * in case we get woken up by DEBUG_END. (At which

	 * point it must be back to the initial true value).

	 */

	THREAD->udebug.go = false;

	THREAD->udebug.cur_event = etype;

	ipc_answer(&TASK->answerbox, call);

	mutex_unlock(&THREAD->udebug.lock);

	mutex_unlock(&TASK->udebug.lock);

	udebug_wait_for_go(&THREAD->udebug.go_wq);

}

/** Thread-creation event hook combined with attaching the thread.

 *

 * Must be called when a new userspace thread is created in the debugged

 * task. Generates a THREAD_B event. Also attaches the thread @a t

 * to the task @a ta.

 *

 * This is necessary to avoid a race condition where the BEGIN and THREAD_READ

 * requests would be handled inbetween attaching the thread and checking it

 * for being in a debugging session to send the THREAD_B event. We could then

 * either miss threads or get some threads both in the thread list

 * and get a THREAD_B event for them.

 *

 * @param t	Structure of the thread being created. Not locked, as the

 *		thread is not executing yet.

 * @param ta	Task to which the thread should be attached.

 */

void udebug_thread_b_event_attach(struct thread *t, struct task *ta)

{

	call_t *call;

	mutex_lock(&TASK->udebug.lock);

	mutex_lock(&THREAD->udebug.lock);

	thread_attach(t, ta);

	LOG("udebug_thread_b_event\n");

	LOG("- check state\n");

	/* Must only generate events when in debugging session */

	if (THREAD->udebug.debug_active != true) {

		LOG("- debug_active: %s, udebug.go: %s\n",

			THREAD->udebug.debug_active ? "yes(+)" : "no(-)",

			THREAD->udebug.go ? "yes(-)" : "no(+)");

		mutex_unlock(&THREAD->udebug.lock);

		mutex_unlock(&TASK->udebug.lock);

		return;

	}

	LOG("- trigger event\n");

	call = THREAD->udebug.go_call;

	THREAD->udebug.go_call = NULL;

	IPC_SET_RETVAL(call->data, 0);

	IPC_SET_ARG1(call->data, UDEBUG_EVENT_THREAD_B);

	IPC_SET_ARG2(call->data, (unative_t)t);

	/*

	 * Make sure udebug.go is false when going to sleep

	 * in case we get woken up by DEBUG_END. (At which

	 * point it must be back to the initial true value).

	 */

	THREAD->udebug.go = false;

	THREAD->udebug.cur_event = UDEBUG_EVENT_THREAD_B;

	ipc_answer(&TASK->answerbox, call);

	mutex_unlock(&THREAD->udebug.lock);

	mutex_unlock(&TASK->udebug.lock);

	LOG("- sleep\n");

	udebug_wait_for_go(&THREAD->udebug.go_wq);

}

/** Thread-termination event hook.

 *

 * Must be called when the current thread is terminating.

 * Generates a THREAD_E event.

 */

void udebug_thread_e_event(void)

{

	call_t *call;

	mutex_lock(&TASK->udebug.lock);

	mutex_lock(&THREAD->udebug.lock);

	LOG("udebug_thread_e_event\n");

	LOG("- check state\n");

	/* Must only generate events when in debugging session. */

	if (THREAD->udebug.debug_active != true) {

/*		printf("- debug_active: %s, udebug.go: %s\n",

			THREAD->udebug.debug_active ? "yes(+)" : "no(-)",

			THREAD->udebug.go ? "yes(-)" : "no(+)");*/

		mutex_unlock(&THREAD->udebug.lock);

		mutex_unlock(&TASK->udebug.lock);

		return;

	}

	LOG("- trigger event\n");

	call = THREAD->udebug.go_call;

	THREAD->udebug.go_call = NULL;

	IPC_SET_RETVAL(call->data, 0);

	IPC_SET_ARG1(call->data, UDEBUG_EVENT_THREAD_E);

	/* Prevent any further debug activity in thread. */

	THREAD->udebug.debug_active = false;

	THREAD->udebug.cur_event = 0;		/* none */

	THREAD->udebug.go = false;	/* set to initial value */

	ipc_answer(&TASK->answerbox, call);

	mutex_unlock(&THREAD->udebug.lock);

	mutex_unlock(&TASK->udebug.lock);

	/* 

	 * This event does not sleep - debugging has finished

	 * in this thread.

	 */

}

/**

 * Terminate task debugging session.

 *

 * Gracefully terminates the debugging session for a task. If the debugger

 * is still waiting for events on some threads, it will receive a

 * FINISHED event for each of them.

 *

 * @param ta	Task structure. ta->udebug.lock must be already locked.

 * @return	Zero on success or negative error code.

 */

int udebug_task_cleanup(struct task *ta)

{

	thread_t *t;

	link_t *cur;

	int flags;

	ipl_t ipl;

	LOG("udebug_task_cleanup()\n");

	LOG("task %" PRIu64 "\n", ta->taskid);

	if (ta->udebug.dt_state != UDEBUG_TS_BEGINNING &&

	    ta->udebug.dt_state != UDEBUG_TS_ACTIVE) {

		LOG("udebug_task_cleanup(): task not being debugged\n");

		return EINVAL;

	}

	/* Finish debugging of all userspace threads */

	for (cur = ta->th_head.next; cur != &ta->th_head; cur = cur->next) {

		t = list_get_instance(cur, thread_t, th_link);

		mutex_lock(&t->udebug.lock);

		ipl = interrupts_disable();

		spinlock_lock(&t->lock);

		flags = t->flags;

		spinlock_unlock(&t->lock);

		interrupts_restore(ipl);

		/* Only process userspace threads. */

		if ((flags & THREAD_FLAG_USPACE) != 0) {

			/* Prevent any further debug activity in thread. */

			t->udebug.debug_active = false;

			t->udebug.cur_event = 0;	/* none */

			/* Is the thread still go? */

			if (t->udebug.go == true) {

				/*

				* Yes, so clear go. As debug_active == false,

				 * this doesn't affect anything.

				 */

				t->udebug.go = false;	

				/* Answer GO call */

				LOG("answer GO call with EVENT_FINISHED\n");

				IPC_SET_RETVAL(t->udebug.go_call->data, 0);

				IPC_SET_ARG1(t->udebug.go_call->data,

				    UDEBUG_EVENT_FINISHED);

				ipc_answer(&ta->answerbox, t->udebug.go_call);

				t->udebug.go_call = NULL;

			} else {

				/*

				 * Debug_stop is already at initial value.

				 * Yet this means the thread needs waking up.

				 */

				/*

				 * t's lock must not be held when calling

				 * waitq_wakeup.

				 */

				waitq_wakeup(&t->udebug.go_wq, WAKEUP_FIRST);

			}

		}

		mutex_unlock(&t->udebug.lock);

	}

	ta->udebug.dt_state = UDEBUG_TS_INACTIVE;

	ta->udebug.debugger = NULL;

	return 0;

}

/** @}

 */