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/*

 * Copyright (c) 2006 Ondrej Palkovsky

 * Copyright (c) 2006 Jakub Jermar

 * 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 genericipc

 * @{

 */

/**

 * @file

 * @brief IRQ notification framework.

 *

 * This framework allows applications to register to receive a notification

 * when interrupt is detected. The application may provide a simple 'top-half'

 * handler as part of its registration, which can perform simple operations

 * (read/write port/memory, add information to notification ipc message).

 *

 * The structure of a notification message is as follows:

 * - METHOD: method as registered by the SYS_IPC_REGISTER_IRQ syscall

 * - ARG1: payload modified by a 'top-half' handler

 * - ARG2: payload modified by a 'top-half' handler

 * - ARG3: payload modified by a 'top-half' handler

 * - ARG4: payload modified by a 'top-half' handler

 * - ARG5: payload modified by a 'top-half' handler

 * - in_phone_hash: interrupt counter (may be needed to assure correct order

 *         in multithreaded drivers)

 *

 * Note on synchronization for ipc_irq_register(), ipc_irq_unregister(),

 * ipc_irq_cleanup() and IRQ handlers:

 *

 *   By always taking all of the uspace IRQ hash table lock, IRQ structure lock

 *   and answerbox lock, we can rule out race conditions between the

 *   registration functions and also the cleanup function. Thus the observer can

 *   either see the IRQ structure present in both the hash table and the

 *   answerbox list or absent in both. Views in which the IRQ structure would be

 *   linked in the hash table but not in the answerbox list, or vice versa, are

 *   not possible.

 *

 *   By always taking the hash table lock and the IRQ structure lock, we can

 *   rule out a scenario in which we would free up an IRQ structure, which is

 *   still referenced by, for example, an IRQ handler. The locking scheme forces

 *   us to lock the IRQ structure only after any progressing IRQs on that

 *   structure are finished. Because we hold the hash table lock, we prevent new

 *   IRQs from taking new references to the IRQ structure.

 */

#include <arch.h>

#include <mm/slab.h>

#include <errno.h>

#include <ddi/irq.h>

#include <ipc/ipc.h>

#include <ipc/irq.h>

#include <syscall/copy.h>

#include <console/console.h>

#include <print.h>

/** Free the top-half pseudocode.

 *

 * @param code		Pointer to the top-half pseudocode.

 */

static void code_free(irq_code_t *code)

{

	if (code) {

		free(code->cmds);

		free(code);

	}

}

/** Copy the top-half pseudocode from userspace into the kernel.

 *

 * @param ucode		Userspace address of the top-half pseudocode.

 *

 * @return		Kernel address of the copied pseudocode.

 */

static irq_code_t *code_from_uspace(irq_code_t *ucode)

{

	irq_code_t *code;

	irq_cmd_t *ucmds;

	int rc;

	code = malloc(sizeof(*code), 0);

	rc = copy_from_uspace(code, ucode, sizeof(*code));

	if (rc != 0) {

		free(code);

		return NULL;

	}

	if (code->cmdcount > IRQ_MAX_PROG_SIZE) {

		free(code);

		return NULL;

	}

	ucmds = code->cmds;

	code->cmds = malloc(sizeof(code->cmds[0]) * code->cmdcount, 0);

	rc = copy_from_uspace(code->cmds, ucmds,

	    sizeof(code->cmds[0]) * code->cmdcount);

	if (rc != 0) {

		free(code->cmds);

		free(code);

		return NULL;

	}

	return code;

}

/** Register an answerbox as a receiving end for IRQ notifications.

 *

 * @param box    Receiving answerbox.

 * @param inr    IRQ number.

 * @param devno  Device number.

 * @param method Method to be associated with the notification.

 * @param ucode  Uspace pointer to top-half pseudocode.

 *

 * @return EBADMEM, ENOENT or EEXISTS on failure or 0 on success.

 *

 */

int ipc_irq_register(answerbox_t *box, inr_t inr, devno_t devno,

    unative_t method, irq_code_t *ucode)

{

	ipl_t ipl;

	irq_code_t *code;

	irq_t *irq;

	link_t *hlp;

	unative_t key[] = {

		(unative_t) inr,

		(unative_t) devno

	};

	if (ucode) {

		code = code_from_uspace(ucode);

		if (!code)

			return EBADMEM;

	} else {

		code = NULL;

	}

	/*

	 * Allocate and populate the IRQ structure.

	 */

	irq = malloc(sizeof(irq_t), 0);

	irq_initialize(irq);

	irq->devno = devno;

	irq->inr = inr;

	irq->claim = ipc_irq_top_half_claim;

	irq->handler = ipc_irq_top_half_handler;

	irq->notif_cfg.notify = true;

	irq->notif_cfg.answerbox = box;

	irq->notif_cfg.method = method;

	irq->notif_cfg.code = code;

	irq->notif_cfg.counter = 0;

	/*

	 * Enlist the IRQ structure in the uspace IRQ hash table and the

	 * answerbox's list.

	 */

	ipl = interrupts_disable();

	spinlock_lock(&irq_uspace_hash_table_lock);

	hlp = hash_table_find(&irq_uspace_hash_table, key);

	if (hlp) {

		irq_t *hirq __attribute__((unused))

		    = hash_table_get_instance(hlp, irq_t, link);

		/* hirq is locked */

		spinlock_unlock(&hirq->lock);

		code_free(code);

		spinlock_unlock(&irq_uspace_hash_table_lock);

		free(irq);

		interrupts_restore(ipl);

		return EEXISTS;

	}

	spinlock_lock(&irq->lock);  /* Not really necessary, but paranoid */

	spinlock_lock(&box->irq_lock);

	hash_table_insert(&irq_uspace_hash_table, key, &irq->link);

	list_append(&irq->notif_cfg.link, &box->irq_head);

	spinlock_unlock(&box->irq_lock);

	spinlock_unlock(&irq->lock);

	spinlock_unlock(&irq_uspace_hash_table_lock);

	interrupts_restore(ipl);

	return EOK;

}

/** Unregister task from IRQ notification.

 *

 * @param box		Answerbox associated with the notification.

 * @param inr		IRQ number.

 * @param devno		Device number.

 */

int ipc_irq_unregister(answerbox_t *box, inr_t inr, devno_t devno)

{

	ipl_t ipl;

	unative_t key[] = {

		(unative_t) inr,

		(unative_t) devno

	};

	link_t *lnk;

	irq_t *irq;

	ipl = interrupts_disable();

	spinlock_lock(&irq_uspace_hash_table_lock);

	lnk = hash_table_find(&irq_uspace_hash_table, key);

	if (!lnk) {

		spinlock_unlock(&irq_uspace_hash_table_lock);

		interrupts_restore(ipl);

		return ENOENT;

	}

	irq = hash_table_get_instance(lnk, irq_t, link);

	/* irq is locked */

	spinlock_lock(&box->irq_lock);

	ASSERT(irq->notif_cfg.answerbox == box);

	/* Free up the pseudo code and associated structures. */

	code_free(irq->notif_cfg.code);

	/* Remove the IRQ from the answerbox's list. */ 

	list_remove(&irq->notif_cfg.link);

	/*

	 * We need to drop the IRQ lock now because hash_table_remove() will try

	 * to reacquire it. That basically violates the natural locking order,

	 * but a deadlock in hash_table_remove() is prevented by the fact that

	 * we already held the IRQ lock and didn't drop the hash table lock in

	 * the meantime.

	 */

	spinlock_unlock(&irq->lock);

	/* Remove the IRQ from the uspace IRQ hash table. */

	hash_table_remove(&irq_uspace_hash_table, key, 2);

	spinlock_unlock(&irq_uspace_hash_table_lock);

	spinlock_unlock(&box->irq_lock);

	/* Free up the IRQ structure. */

	free(irq);

	interrupts_restore(ipl);

	return EOK;

}

/** Disconnect all IRQ notifications from an answerbox.

 *

 * This function is effective because the answerbox contains

 * list of all irq_t structures that are registered to

 * send notifications to it.

 *

 * @param box		Answerbox for which we want to carry out the cleanup.

 */

void ipc_irq_cleanup(answerbox_t *box)

{

	ipl_t ipl;

loop:

	ipl = interrupts_disable();

	spinlock_lock(&irq_uspace_hash_table_lock);

	spinlock_lock(&box->irq_lock);

	while (box->irq_head.next != &box->irq_head) {

		link_t *cur = box->irq_head.next;

		irq_t *irq;

		DEADLOCK_PROBE_INIT(p_irqlock);

		unative_t key[2];

		irq = list_get_instance(cur, irq_t, notif_cfg.link);

		if (!spinlock_trylock(&irq->lock)) {

			/*

			 * Avoid deadlock by trying again.

			 */

			spinlock_unlock(&box->irq_lock);

			spinlock_unlock(&irq_uspace_hash_table_lock);

			interrupts_restore(ipl);

			DEADLOCK_PROBE(p_irqlock, DEADLOCK_THRESHOLD);

			goto loop;

		}

		key[0] = irq->inr;

		key[1] = irq->devno;

		ASSERT(irq->notif_cfg.answerbox == box);

		/* Unlist from the answerbox. */

		list_remove(&irq->notif_cfg.link);

		/* Free up the pseudo code and associated structures. */

		code_free(irq->notif_cfg.code);

		/*

		 * We need to drop the IRQ lock now because hash_table_remove()

		 * will try to reacquire it. That basically violates the natural

		 * locking order, but a deadlock in hash_table_remove() is

		 * prevented by the fact that we already held the IRQ lock and

		 * didn't drop the hash table lock in the meantime.

		 */

		spinlock_unlock(&irq->lock);

		/* Remove from the hash table. */

		hash_table_remove(&irq_uspace_hash_table, key, 2);

		free(irq);

	}

	spinlock_unlock(&box->irq_lock);

	spinlock_unlock(&irq_uspace_hash_table_lock);

	interrupts_restore(ipl);

}

/** Add a call to the proper answerbox queue.

 *

 * Assume irq->lock is locked.

 *

 * @param irq		IRQ structure referencing the target answerbox.

 * @param call		IRQ notification call.

 */

static void send_call(irq_t *irq, call_t *call)

{

	spinlock_lock(&irq->notif_cfg.answerbox->irq_lock);

	list_append(&call->link, &irq->notif_cfg.answerbox->irq_notifs);

	spinlock_unlock(&irq->notif_cfg.answerbox->irq_lock);

	waitq_wakeup(&irq->notif_cfg.answerbox->wq, WAKEUP_FIRST);

}

/** Apply the top-half pseudo code to find out whether to accept the IRQ or not.

 *

 * @param irq		IRQ structure.

 *

 * @return		IRQ_ACCEPT if the interrupt is accepted by the

 *			pseudocode. IRQ_DECLINE otherwise.

 */

irq_ownership_t ipc_irq_top_half_claim(irq_t *irq)

{

	unsigned int i;

	unative_t dstval;

	irq_code_t *code = irq->notif_cfg.code;

	unative_t *scratch = irq->notif_cfg.scratch;

	if (!irq->notif_cfg.notify)

		return IRQ_DECLINE;

	if (!code)

		return IRQ_DECLINE;

	for (i = 0; i < code->cmdcount; i++) {

		unsigned int srcarg = code->cmds[i].srcarg;

		unsigned int dstarg = code->cmds[i].dstarg;

		if (srcarg >= IPC_CALL_LEN)

			break;

		if (dstarg >= IPC_CALL_LEN)

			break;

		switch (code->cmds[i].cmd) {

		case CMD_PIO_READ_8:

			dstval = pio_read_8((ioport8_t *) code->cmds[i].addr);

			if (dstarg)

				scratch[dstarg] = dstval;

			break;

		case CMD_PIO_READ_16:

			dstval = pio_read_16((ioport16_t *) code->cmds[i].addr);

			if (dstarg)

				scratch[dstarg] = dstval;

			break;

		case CMD_PIO_READ_32:

			dstval = pio_read_32((ioport32_t *) code->cmds[i].addr);

			if (dstarg)

				scratch[dstarg] = dstval;

			break;

		case CMD_PIO_WRITE_8:

			pio_write_8((ioport8_t *) code->cmds[i].addr,

			    (uint8_t) code->cmds[i].value);

			break;

		case CMD_PIO_WRITE_16:

			pio_write_16((ioport16_t *) code->cmds[i].addr,

			    (uint16_t) code->cmds[i].value);

			break;

		case CMD_PIO_WRITE_32:

			pio_write_32((ioport32_t *) code->cmds[i].addr,

			    (uint32_t) code->cmds[i].value);

			break;

		case CMD_BTEST:

			if (srcarg && dstarg) {

				dstval = scratch[srcarg] & code->cmds[i].value;

				scratch[dstarg] = dstval;

			}

			break;

		case CMD_PREDICATE:

			if (srcarg && !scratch[srcarg]) {

				i += code->cmds[i].value;

				continue;

			}

			break;

		case CMD_ACCEPT:

			return IRQ_ACCEPT;

			break;

		case CMD_DECLINE:

		default:

			return IRQ_DECLINE;

		}

	}

	return IRQ_DECLINE;

}

/* IRQ top-half handler.

 *

 * We expect interrupts to be disabled and the irq->lock already held.

 *

 * @param irq		IRQ structure.

 */

void ipc_irq_top_half_handler(irq_t *irq)

{

	ASSERT(irq);

	if (irq->notif_cfg.answerbox) {

		call_t *call;

		call = ipc_call_alloc(FRAME_ATOMIC);

		if (!call)

			return;

		call->flags |= IPC_CALL_NOTIF;

		/* Put a counter to the message */

		call->priv = ++irq->notif_cfg.counter;

		/* Set up args */

		IPC_SET_METHOD(call->data, irq->notif_cfg.method);

		IPC_SET_ARG1(call->data, irq->notif_cfg.scratch[1]);

		IPC_SET_ARG2(call->data, irq->notif_cfg.scratch[2]);

		IPC_SET_ARG3(call->data, irq->notif_cfg.scratch[3]);

		IPC_SET_ARG4(call->data, irq->notif_cfg.scratch[4]);

		IPC_SET_ARG5(call->data, irq->notif_cfg.scratch[5]);

		send_call(irq, call);

	}

}

/** Send notification message.

 *

 * @param irq		IRQ structure.

 * @param a1		Driver-specific payload argument.

 * @param a2		Driver-specific payload argument.

 * @param a3		Driver-specific payload argument.

 * @param a4		Driver-specific payload argument.

 * @param a5		Driver-specific payload argument.

 */

void ipc_irq_send_msg(irq_t *irq, unative_t a1, unative_t a2, unative_t a3,

    unative_t a4, unative_t a5)

{

	call_t *call;

	spinlock_lock(&irq->lock);

	if (irq->notif_cfg.answerbox) {

		call = ipc_call_alloc(FRAME_ATOMIC);

		if (!call) {

			spinlock_unlock(&irq->lock);

			return;

		}

		call->flags |= IPC_CALL_NOTIF;

		/* Put a counter to the message */

		call->priv = ++irq->notif_cfg.counter;

		IPC_SET_METHOD(call->data, irq->notif_cfg.method);

		IPC_SET_ARG1(call->data, a1);

		IPC_SET_ARG2(call->data, a2);

		IPC_SET_ARG3(call->data, a3);

		IPC_SET_ARG4(call->data, a4);

		IPC_SET_ARG5(call->data, a5);

		send_call(irq, call);

	}

	spinlock_unlock(&irq->lock);

}

/** @}

 */