usbtty.c

F:worksip2440a board可启动u-boot-like.tar.gz F:worksip2440a board可启动u-boot-like.tar.gz

	/* Now, set up USB controller and infrastructure */
	udc_init ();		/* Basic USB initialization */

	usbtty_init_strings ();
	usbtty_init_instances ();

	udc_startup_events (device_instance);	/* Enable our device, initialize udc pointers */
	udc_connect ();		/* Enable pullup for host detection */

	usbtty_init_endpoints ();

	/* Device initialization */
	memset (&usbttydev, 0, sizeof (usbttydev));

	strcpy (usbttydev.name, "usbtty");
	usbttydev.ext = 0;	/* No extensions */
	usbttydev.flags = DEV_FLAGS_INPUT | DEV_FLAGS_OUTPUT;
	usbttydev.tstc = usbtty_tstc;	/* 'tstc' function */
	usbttydev.getc = usbtty_getc;	/* 'getc' function */
	usbttydev.putc = usbtty_putc;	/* 'putc' function */
	usbttydev.puts = usbtty_puts;	/* 'puts' function */

	rc = device_register (&usbttydev);

	return (rc == 0) ? 1 : rc;
}

static void usbtty_init_strings (void)
{
	struct usb_string_descriptor *string;

	string = (struct usb_string_descriptor *) wstrManufacturer;
	string->bLength = sizeof (wstrManufacturer);
	string->bDescriptorType = USB_DT_STRING;
	str2wide (CONFIG_USBD_MANUFACTURER, string->wData);

	string = (struct usb_string_descriptor *) wstrProduct;
	string->bLength = sizeof (wstrProduct);
	string->bDescriptorType = USB_DT_STRING;
	str2wide (CONFIG_USBD_PRODUCT_NAME, string->wData);

	string = (struct usb_string_descriptor *) wstrSerial;
	string->bLength = 2 + 2*strlen(serial_number);
	string->bDescriptorType = USB_DT_STRING;
	str2wide (serial_number, string->wData);

	string = (struct usb_string_descriptor *) wstrConfiguration;
	string->bLength = sizeof (wstrConfiguration);
	string->bDescriptorType = USB_DT_STRING;
	str2wide (CONFIG_USBD_CONFIGURATION_STR, string->wData);

	string = (struct usb_string_descriptor *) wstrInterface;
	string->bLength = sizeof (wstrInterface);
	string->bDescriptorType = USB_DT_STRING;
	str2wide (CONFIG_USBD_INTERFACE_STR, string->wData);

	/* Now, initialize the string table for ep0 handling */
	usb_strings = usbtty_string_table;
}

static void usbtty_init_instances (void)
{
	int i;

	/* initialize device instance */
	memset (device_instance, 0, sizeof (struct usb_device_instance));
	device_instance->device_state = STATE_INIT;
	device_instance->device_descriptor = &device_descriptor;
	device_instance->event = usbtty_event_handler;
	device_instance->bus = bus_instance;
	device_instance->configurations = NUM_CONFIGS;
	device_instance->configuration_instance_array = config_instance;

	/* initialize bus instance */
	memset (bus_instance, 0, sizeof (struct usb_bus_instance));
	bus_instance->device = device_instance;
	bus_instance->endpoint_array = endpoint_instance;
	bus_instance->max_endpoints = 1;
	bus_instance->maxpacketsize = 64;
	bus_instance->serial_number_str = serial_number;

	/* configuration instance */
	memset (config_instance, 0,
		sizeof (struct usb_configuration_instance));
	config_instance->interfaces = NUM_INTERFACES;
	config_instance->configuration_descriptor = config_descriptors;
	config_instance->interface_instance_array = interface_instance;

	/* interface instance */
	memset (interface_instance, 0,
		sizeof (struct usb_interface_instance));
	interface_instance->alternates = 1;
	interface_instance->alternates_instance_array = alternate_instance;

	/* alternates instance */
	memset (alternate_instance, 0,
		sizeof (struct usb_alternate_instance));
	alternate_instance->interface_descriptor = interface_descriptors;
	alternate_instance->endpoints = NUM_ENDPOINTS;
	alternate_instance->endpoints_descriptor_array = ep_descriptor_ptrs;

	/* endpoint instances */
	memset (&endpoint_instance[0], 0,
		sizeof (struct usb_endpoint_instance));
	endpoint_instance[0].endpoint_address = 0;
	endpoint_instance[0].rcv_packetSize = EP0_MAX_PACKET_SIZE;
	endpoint_instance[0].rcv_attributes = USB_ENDPOINT_XFER_CONTROL;
	endpoint_instance[0].tx_packetSize = EP0_MAX_PACKET_SIZE;
	endpoint_instance[0].tx_attributes = USB_ENDPOINT_XFER_CONTROL;
	udc_setup_ep (device_instance, 0, &endpoint_instance[0]);

	for (i = 1; i <= NUM_ENDPOINTS; i++) {
		memset (&endpoint_instance[i], 0,
			sizeof (struct usb_endpoint_instance));

		endpoint_instance[i].endpoint_address =
			ep_descriptors[i - 1].bEndpointAddress;

		endpoint_instance[i].rcv_packetSize =
			ep_descriptors[i - 1].wMaxPacketSize;
		endpoint_instance[i].rcv_attributes =
			ep_descriptors[i - 1].bmAttributes;

		endpoint_instance[i].tx_packetSize =
			ep_descriptors[i - 1].wMaxPacketSize;
		endpoint_instance[i].tx_attributes =
			ep_descriptors[i - 1].bmAttributes;

		urb_link_init (&endpoint_instance[i].rcv);
		urb_link_init (&endpoint_instance[i].rdy);
		urb_link_init (&endpoint_instance[i].tx);
		urb_link_init (&endpoint_instance[i].done);

		if (endpoint_instance[i].endpoint_address & USB_DIR_IN)
			endpoint_instance[i].tx_urb =
				usbd_alloc_urb (device_instance,
						&endpoint_instance[i]);
		else
			endpoint_instance[i].rcv_urb =
				usbd_alloc_urb (device_instance,
						&endpoint_instance[i]);
	}
}

static void usbtty_init_endpoints (void)
{
	int i;

	bus_instance->max_endpoints = NUM_ENDPOINTS + 1;
	for (i = 0; i <= NUM_ENDPOINTS; i++) {
		udc_setup_ep (device_instance, i, &endpoint_instance[i]);
	}
}


/*********************************************************************************/

static struct urb *next_urb (struct usb_device_instance *device,
			     struct usb_endpoint_instance *endpoint)
{
	struct urb *current_urb = NULL;
	int space;

	/* If there's a queue, then we should add to the last urb */
	if (!endpoint->tx_queue) {
		current_urb = endpoint->tx_urb;
	} else {
		/* Last urb from tx chain */
		current_urb =
			p2surround (struct urb, link, endpoint->tx.prev);
	}

	/* Make sure this one has enough room */
	space = current_urb->buffer_length - current_urb->actual_length;
	if (space > 0) {
		return current_urb;
	} else {		/* No space here */
		/* First look at done list */
		current_urb = first_urb_detached (&endpoint->done);
		if (!current_urb) {
			current_urb = usbd_alloc_urb (device, endpoint);
		}

		urb_append (&endpoint->tx, current_urb);
		endpoint->tx_queue++;
	}
	return current_urb;
}

static int write_buffer (circbuf_t * buf)
{
	if (!usbtty_configured ()) {
		return 0;
	}

	if (buf->size) {

		struct usb_endpoint_instance *endpoint =
			&endpoint_instance[TX_ENDPOINT];
		struct urb *current_urb = NULL;
		char *dest;

		int space_avail;
		int popnum, popped;
		int total = 0;

		/* Break buffer into urb sized pieces, and link each to the endpoint */
		while (buf->size > 0) {
			current_urb = next_urb (device_instance, endpoint);
			if (!current_urb) {
				TTYERR ("current_urb is NULL, buf->size %d\n",
					buf->size);
				return total;
			}

			dest = current_urb->buffer +
				current_urb->actual_length;

			space_avail =
				current_urb->buffer_length -
				current_urb->actual_length;
			popnum = MIN (space_avail, buf->size);
			if (popnum == 0)
				break;

			popped = buf_pop (buf, dest, popnum);
			if (popped == 0)
				break;
			current_urb->actual_length += popped;
			total += popped;

			/* If endpoint->last == 0, then transfers have not started on this endpoint */
			if (endpoint->last == 0) {
				udc_endpoint_write (endpoint);
			}

		}		/* end while */
		return total;
	}			/* end if tx_urb */

	return 0;
}

static int fill_buffer (circbuf_t * buf)
{
	struct usb_endpoint_instance *endpoint =
		&endpoint_instance[RECV_ENDPOINT];

	if (endpoint->rcv_urb && endpoint->rcv_urb->actual_length) {
		unsigned int nb = endpoint->rcv_urb->actual_length;
		char *src = (char *) endpoint->rcv_urb->buffer;

		buf_push (buf, src, nb);
		endpoint->rcv_urb->actual_length = 0;

		return nb;
	}

	return 0;
}

static int usbtty_configured (void)
{
	return usbtty_configured_flag;
}

/*********************************************************************************/

static void usbtty_event_handler (struct usb_device_instance *device,
				  usb_device_event_t event, int data)
{
	switch (event) {
	case DEVICE_RESET:
	case DEVICE_BUS_INACTIVE:
		usbtty_configured_flag = 0;
		break;
	case DEVICE_CONFIGURED:
		usbtty_configured_flag = 1;
		break;

	case DEVICE_ADDRESS_ASSIGNED:
		usbtty_init_endpoints ();

	default:
		break;
	}
}

/*********************************************************************************/


/*
 * Since interrupt handling has not yet been implemented, we use this function
 * to handle polling.  This is called by the tstc,getc,putc,puts routines to
 * update the USB state.
 */
void usbtty_poll (void)
{
	/* New interrupts? */
	pretend_interrupts ();

	/* Write any output data to host buffer (do this before checking interrupts to avoid missing one) */
	if (usbtty_configured ()) {
		write_buffer (&usbtty_output);
	}

	/* New interrupts? */
	pretend_interrupts ();

	/* Check for new data from host.. (do this after checking interrupts to get latest data) */
	if (usbtty_configured ()) {
		fill_buffer (&usbtty_input);
	}

	/* New interrupts? */
	pretend_interrupts ();
}

static void pretend_interrupts (void)
{
	/* Loop while we have interrupts.
	 * If we don't do this, the input chain
	 * polling delay is likely to miss
	 * host requests.
	 */
	while (inw (UDC_IRQ_SRC) & ~UDC_SOF_Flg) {
		/* Handle any new IRQs */
		omap1510_udc_irq ();
		omap1510_udc_noniso_irq ();
	}
}
#endif