src/class/cdc/cdc_device.c - third_party/github/hathach/tinyusb - Git at Google

 /*
  * The MIT License (MIT)
  *
  * Copyright (c) 2019 Ha Thach (tinyusb.org)
  *
  * Permission is hereby granted, free of charge, to any person obtaining a copy
  * of this software and associated documentation files (the "Software"), to deal
  * in the Software without restriction, including without limitation the rights
  * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
  * copies of the Software, and to permit persons to whom the Software is
  * furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in
  * all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
  * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
  * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
  * THE SOFTWARE.
  *
  * This file is part of the TinyUSB stack.
  */

 #include "tusb_option.h"

 #if (CFG_TUD_ENABLED && CFG_TUD_CDC)

 #include "device/usbd.h"
 #include "device/usbd_pvt.h"

 #include "cdc_device.h"

 // Level where CFG_TUSB_DEBUG must be at least for this driver is logged
 #ifndef CFG_TUD_CDC_LOG_LEVEL
   #define CFG_TUD_CDC_LOG_LEVEL   CFG_TUD_LOG_LEVEL
 #endif

 #define TU_LOG_DRV(...)   TU_LOG(CFG_TUD_CDC_LOG_LEVEL, __VA_ARGS__)

 //--------------------------------------------------------------------+
 // MACRO CONSTANT TYPEDEF
 //--------------------------------------------------------------------+
 #define BULK_PACKET_SIZE (TUD_OPT_HIGH_SPEED ? 512 : 64)

 typedef struct {
   uint8_t itf_num;
   uint8_t ep_notif;
   uint8_t ep_in;
   uint8_t ep_out;

   // Bit 0:  DTR (Data Terminal Ready), Bit 1: RTS (Request to Send)
   uint8_t line_state;

   /*------------- From this point, data is not cleared by bus reset -------------*/
   char wanted_char;
   TU_ATTR_ALIGNED(4) cdc_line_coding_t line_coding;

   // FIFO
   tu_fifo_t rx_ff;
   tu_fifo_t tx_ff;

   uint8_t rx_ff_buf[CFG_TUD_CDC_RX_BUFSIZE];
   uint8_t tx_ff_buf[CFG_TUD_CDC_TX_BUFSIZE];

   OSAL_MUTEX_DEF(rx_ff_mutex);
   OSAL_MUTEX_DEF(tx_ff_mutex);
 } cdcd_interface_t;

 #define ITF_MEM_RESET_SIZE   offsetof(cdcd_interface_t, wanted_char)

 typedef struct {
   TUD_EPBUF_DEF(epout, CFG_TUD_CDC_EP_BUFSIZE);
   TUD_EPBUF_DEF(epin, CFG_TUD_CDC_EP_BUFSIZE);
 } cdcd_epbuf_t;

 //--------------------------------------------------------------------+
 // INTERNAL OBJECT & FUNCTION DECLARATION
 //--------------------------------------------------------------------+
 static cdcd_interface_t _cdcd_itf[CFG_TUD_CDC];
 CFG_TUD_MEM_SECTION static cdcd_epbuf_t _cdcd_epbuf[CFG_TUD_CDC];

 static tud_cdc_configure_fifo_t _cdcd_fifo_cfg;

 static bool _prep_out_transaction(uint8_t itf) {
   const uint8_t rhport = 0;
   cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
   cdcd_epbuf_t* p_epbuf = &_cdcd_epbuf[itf];

   // Skip if usb is not ready yet
   TU_VERIFY(tud_ready() && p_cdc->ep_out);

   uint16_t available = tu_fifo_remaining(&p_cdc->rx_ff);

   // Prepare for incoming data but only allow what we can store in the ring buffer.
   // TODO Actually we can still carry out the transfer, keeping count of received bytes
   // and slowly move it to the FIFO when read().
   // This pre-check reduces endpoint claiming
   TU_VERIFY(available >= CFG_TUD_CDC_EP_BUFSIZE);

   // claim endpoint
   TU_VERIFY(usbd_edpt_claim(rhport, p_cdc->ep_out));

   // fifo can be changed before endpoint is claimed
   available = tu_fifo_remaining(&p_cdc->rx_ff);

   if (available >= CFG_TUD_CDC_EP_BUFSIZE) {
     return usbd_edpt_xfer(rhport, p_cdc->ep_out, p_epbuf->epout, CFG_TUD_CDC_EP_BUFSIZE);
   } else {
     // Release endpoint since we don't make any transfer
     usbd_edpt_release(rhport, p_cdc->ep_out);
     return false;
   }
 }

 //--------------------------------------------------------------------+
 // APPLICATION API
 //--------------------------------------------------------------------+

 bool tud_cdc_configure_fifo(const tud_cdc_configure_fifo_t* cfg) {
   TU_VERIFY(cfg);
   _cdcd_fifo_cfg = (*cfg);
   return true;
 }

 bool tud_cdc_n_ready(uint8_t itf) {
   return tud_ready() && _cdcd_itf[itf].ep_in != 0 && _cdcd_itf[itf].ep_out != 0;
 }

 bool tud_cdc_n_connected(uint8_t itf) {
   // DTR (bit 0) active  is considered as connected
   return tud_ready() && tu_bit_test(_cdcd_itf[itf].line_state, 0);
 }

 uint8_t tud_cdc_n_get_line_state(uint8_t itf) {
   return _cdcd_itf[itf].line_state;
 }

 void tud_cdc_n_get_line_coding(uint8_t itf, cdc_line_coding_t* coding) {
   (*coding) = _cdcd_itf[itf].line_coding;
 }

 void tud_cdc_n_set_wanted_char(uint8_t itf, char wanted) {
   _cdcd_itf[itf].wanted_char = wanted;
 }

 //--------------------------------------------------------------------+
 // READ API
 //--------------------------------------------------------------------+
 uint32_t tud_cdc_n_available(uint8_t itf) {
   return tu_fifo_count(&_cdcd_itf[itf].rx_ff);
 }

 uint32_t tud_cdc_n_read(uint8_t itf, void* buffer, uint32_t bufsize) {
   cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
   uint32_t num_read = tu_fifo_read_n(&p_cdc->rx_ff, buffer, (uint16_t) TU_MIN(bufsize, UINT16_MAX));
   _prep_out_transaction(itf);
   return num_read;
 }

 bool tud_cdc_n_peek(uint8_t itf, uint8_t* chr) {
   return tu_fifo_peek(&_cdcd_itf[itf].rx_ff, chr);
 }

 void tud_cdc_n_read_flush(uint8_t itf) {
   cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
   tu_fifo_clear(&p_cdc->rx_ff);
   _prep_out_transaction(itf);
 }

 //--------------------------------------------------------------------+
 // WRITE API
 //--------------------------------------------------------------------+
 uint32_t tud_cdc_n_write(uint8_t itf, const void* buffer, uint32_t bufsize) {
   cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
   uint16_t ret = tu_fifo_write_n(&p_cdc->tx_ff, buffer, (uint16_t) TU_MIN(bufsize, UINT16_MAX));

   // flush if queue more than packet size
   if (tu_fifo_count(&p_cdc->tx_ff) >= BULK_PACKET_SIZE
       #if CFG_TUD_CDC_TX_BUFSIZE < BULK_PACKET_SIZE
       || tu_fifo_full(&p_cdc->tx_ff) // check full if fifo size is less than packet size
       #endif
       ) {
     tud_cdc_n_write_flush(itf);
   }

   return ret;
 }

 uint32_t tud_cdc_n_write_flush(uint8_t itf) {
   cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
   cdcd_epbuf_t* p_epbuf = &_cdcd_epbuf[itf];

   // Skip if usb is not ready yet
   TU_VERIFY(tud_ready(), 0);

   // No data to send
   if (!tu_fifo_count(&p_cdc->tx_ff)) {
     return 0;
   }

   const uint8_t rhport = 0;

   // Claim the endpoint
   TU_VERIFY(usbd_edpt_claim(rhport, p_cdc->ep_in), 0);

   // Pull data from FIFO
   const uint16_t count = tu_fifo_read_n(&p_cdc->tx_ff, p_epbuf->epin, CFG_TUD_CDC_EP_BUFSIZE);

   if (count) {
     TU_ASSERT(usbd_edpt_xfer(rhport, p_cdc->ep_in, p_epbuf->epin, count), 0);
     return count;
   } else {
     // Release endpoint since we don't make any transfer
     // Note: data is dropped if terminal is not connected
     usbd_edpt_release(rhport, p_cdc->ep_in);
     return 0;
   }
 }

 uint32_t tud_cdc_n_write_available(uint8_t itf) {
   return tu_fifo_remaining(&_cdcd_itf[itf].tx_ff);
 }

 bool tud_cdc_n_write_clear(uint8_t itf) {
   return tu_fifo_clear(&_cdcd_itf[itf].tx_ff);
 }

 //--------------------------------------------------------------------+
 // USBD Driver API
 //--------------------------------------------------------------------+
 void cdcd_init(void) {
   tu_memclr(_cdcd_itf, sizeof(_cdcd_itf));
   tu_memclr(&_cdcd_fifo_cfg, sizeof(_cdcd_fifo_cfg));

   for (uint8_t i = 0; i < CFG_TUD_CDC; i++) {
     cdcd_interface_t* p_cdc = &_cdcd_itf[i];

     p_cdc->wanted_char = (char) -1;

     // default line coding is : stop bit = 1, parity = none, data bits = 8
     p_cdc->line_coding.bit_rate = 115200;
     p_cdc->line_coding.stop_bits = 0;
     p_cdc->line_coding.parity = 0;
     p_cdc->line_coding.data_bits = 8;

     // Config RX fifo
     tu_fifo_config(&p_cdc->rx_ff, p_cdc->rx_ff_buf, TU_ARRAY_SIZE(p_cdc->rx_ff_buf), 1, false);

     // Config TX fifo as overwritable at initialization and will be changed to non-overwritable
     // if terminal supports DTR bit. Without DTR we do not know if data is actually polled by terminal.
     // In this way, the most current data is prioritized.
     tu_fifo_config(&p_cdc->tx_ff, p_cdc->tx_ff_buf, TU_ARRAY_SIZE(p_cdc->tx_ff_buf), 1, true);

     #if OSAL_MUTEX_REQUIRED
     osal_mutex_t mutex_rd = osal_mutex_create(&p_cdc->rx_ff_mutex);
     osal_mutex_t mutex_wr = osal_mutex_create(&p_cdc->tx_ff_mutex);
     TU_ASSERT(mutex_rd != NULL && mutex_wr != NULL, );

     tu_fifo_config_mutex(&p_cdc->rx_ff, NULL, mutex_rd);
     tu_fifo_config_mutex(&p_cdc->tx_ff, mutex_wr, NULL);
     #endif
   }
 }

 bool cdcd_deinit(void) {
   #if OSAL_MUTEX_REQUIRED
   for(uint8_t i=0; i<CFG_TUD_CDC; i++) {
     cdcd_interface_t* p_cdc = &_cdcd_itf[i];
     osal_mutex_t mutex_rd = p_cdc->rx_ff.mutex_rd;
     osal_mutex_t mutex_wr = p_cdc->tx_ff.mutex_wr;

     if (mutex_rd) {
       osal_mutex_delete(mutex_rd);
       tu_fifo_config_mutex(&p_cdc->rx_ff, NULL, NULL);
     }

     if (mutex_wr) {
       osal_mutex_delete(mutex_wr);
       tu_fifo_config_mutex(&p_cdc->tx_ff, NULL, NULL);
     }
   }
   #endif

   return true;
 }

 void cdcd_reset(uint8_t rhport) {
   (void) rhport;

   for (uint8_t i = 0; i < CFG_TUD_CDC; i++) {
     cdcd_interface_t* p_cdc = &_cdcd_itf[i];

     tu_memclr(p_cdc, ITF_MEM_RESET_SIZE);
     if (!_cdcd_fifo_cfg.rx_persistent) {
       tu_fifo_clear(&p_cdc->rx_ff);
     }
     if (!_cdcd_fifo_cfg.tx_persistent) {
       tu_fifo_clear(&p_cdc->tx_ff);
     }
     tu_fifo_set_overwritable(&p_cdc->tx_ff, true);
   }
 }

 uint16_t cdcd_open(uint8_t rhport, const tusb_desc_interface_t* itf_desc, uint16_t max_len) {
   // Only support ACM subclass
   TU_VERIFY( TUSB_CLASS_CDC                           == itf_desc->bInterfaceClass &&
              CDC_COMM_SUBCLASS_ABSTRACT_CONTROL_MODEL == itf_desc->bInterfaceSubClass, 0);

   // Find available interface
   cdcd_interface_t* p_cdc;
   uint8_t cdc_id;
   for (cdc_id = 0; cdc_id < CFG_TUD_CDC; cdc_id++) {
     p_cdc = &_cdcd_itf[cdc_id];
     if (p_cdc->ep_in == 0) {
       break;
     }
   }
   TU_ASSERT(cdc_id < CFG_TUD_CDC, 0);

   //------------- Control Interface -------------//
   p_cdc->itf_num = itf_desc->bInterfaceNumber;

   uint16_t drv_len = sizeof(tusb_desc_interface_t);
   const uint8_t* p_desc = tu_desc_next(itf_desc);

   // Communication Functional Descriptors
   while (TUSB_DESC_CS_INTERFACE == tu_desc_type(p_desc) && drv_len <= max_len) {
     drv_len += tu_desc_len(p_desc);
     p_desc = tu_desc_next(p_desc);
   }

   if (TUSB_DESC_ENDPOINT == tu_desc_type(p_desc)) {
     // notification endpoint
     const tusb_desc_endpoint_t* desc_ep = (const tusb_desc_endpoint_t*) p_desc;

     TU_ASSERT(usbd_edpt_open(rhport, desc_ep), 0);
     p_cdc->ep_notif = desc_ep->bEndpointAddress;

     drv_len += tu_desc_len(p_desc);
     p_desc = tu_desc_next(p_desc);
   }

   //------------- Data Interface (if any) -------------//
   if ((TUSB_DESC_INTERFACE == tu_desc_type(p_desc)) &&
       (TUSB_CLASS_CDC_DATA == ((const tusb_desc_interface_t*) p_desc)->bInterfaceClass)) {
     // next to endpoint descriptor
     drv_len += tu_desc_len(p_desc);
     p_desc = tu_desc_next(p_desc);

     // Open endpoint pair
     TU_ASSERT(usbd_open_edpt_pair(rhport, p_desc, 2, TUSB_XFER_BULK, &p_cdc->ep_out, &p_cdc->ep_in), 0);

     drv_len += 2 * sizeof(tusb_desc_endpoint_t);
   }

   // Prepare for incoming data
   _prep_out_transaction(cdc_id);

   return drv_len;
 }

 // Invoked when a control transfer occurred on an interface of this class
 // Driver response accordingly to the request and the transfer stage (setup/data/ack)
 // return false to stall control endpoint (e.g unsupported request)
 bool cdcd_control_xfer_cb(uint8_t rhport, uint8_t stage, const tusb_control_request_t* request) {
   // Handle class request only
   TU_VERIFY(request->bmRequestType_bit.type == TUSB_REQ_TYPE_CLASS);

   uint8_t itf;
   cdcd_interface_t* p_cdc;

   // Identify which interface to use
   for (itf = 0; itf < CFG_TUD_CDC; itf++) {
     p_cdc = &_cdcd_itf[itf];
     if (p_cdc->itf_num == request->wIndex) {
       break;
     }
   }
   TU_VERIFY(itf < CFG_TUD_CDC);

   switch (request->bRequest) {
     case CDC_REQUEST_SET_LINE_CODING:
       if (stage == CONTROL_STAGE_SETUP) {
         TU_LOG_DRV("  Set Line Coding\r\n");
         tud_control_xfer(rhport, request, &p_cdc->line_coding, sizeof(cdc_line_coding_t));
       } else if (stage == CONTROL_STAGE_ACK) {
         if (tud_cdc_line_coding_cb) {
           tud_cdc_line_coding_cb(itf, &p_cdc->line_coding);
         }
       }
       break;

     case CDC_REQUEST_GET_LINE_CODING:
       if (stage == CONTROL_STAGE_SETUP) {
         TU_LOG_DRV("  Get Line Coding\r\n");
         tud_control_xfer(rhport, request, &p_cdc->line_coding, sizeof(cdc_line_coding_t));
       }
       break;

     case CDC_REQUEST_SET_CONTROL_LINE_STATE:
       if (stage == CONTROL_STAGE_SETUP) {
         tud_control_status(rhport, request);
       } else if (stage == CONTROL_STAGE_ACK) {
         // CDC PSTN v1.2 section 6.3.12
         // Bit 0: Indicates if DTE is present or not.
         //        This signal corresponds to V.24 signal 108/2 and RS-232 signal DTR (Data Terminal Ready)
         // Bit 1: Carrier control for half-duplex modems.
         //        This signal corresponds to V.24 signal 105 and RS-232 signal RTS (Request to Send)
         bool const dtr = tu_bit_test(request->wValue, 0);
         bool const rts = tu_bit_test(request->wValue, 1);

         p_cdc->line_state = (uint8_t) request->wValue;

         // Disable fifo overwriting if DTR bit is set
         tu_fifo_set_overwritable(&p_cdc->tx_ff, !dtr);

         TU_LOG_DRV("  Set Control Line State: DTR = %d, RTS = %d\r\n", dtr, rts);

         // Invoke callback
         if (tud_cdc_line_state_cb) {
           tud_cdc_line_state_cb(itf, dtr, rts);
         }
       }
       break;

     case CDC_REQUEST_SEND_BREAK:
       if (stage == CONTROL_STAGE_SETUP) {
         tud_control_status(rhport, request);
       } else if (stage == CONTROL_STAGE_ACK) {
         TU_LOG_DRV("  Send Break\r\n");
         if (tud_cdc_send_break_cb) {
           tud_cdc_send_break_cb(itf, request->wValue);
         }
       }
       break;

     default:
       return false; // stall unsupported request
   }

   return true;
 }

 bool cdcd_xfer_cb(uint8_t rhport, uint8_t ep_addr, xfer_result_t result, uint32_t xferred_bytes) {
   (void) result;

   uint8_t itf;
   cdcd_interface_t* p_cdc;

   // Identify which interface to use
   for (itf = 0; itf < CFG_TUD_CDC; itf++) {
     p_cdc = &_cdcd_itf[itf];
     if ((ep_addr == p_cdc->ep_out) || (ep_addr == p_cdc->ep_in)) {
       break;
     }
   }
   TU_ASSERT(itf < CFG_TUD_CDC);
   cdcd_epbuf_t* p_epbuf = &_cdcd_epbuf[itf];

   // Received new data
   if (ep_addr == p_cdc->ep_out) {
     tu_fifo_write_n(&p_cdc->rx_ff, p_epbuf->epout, (uint16_t) xferred_bytes);

     // Check for wanted char and invoke callback if needed
     if (tud_cdc_rx_wanted_cb && (((signed char) p_cdc->wanted_char) != -1)) {
       for (uint32_t i = 0; i < xferred_bytes; i++) {
         if ((p_cdc->wanted_char == p_epbuf->epout[i]) && !tu_fifo_empty(&p_cdc->rx_ff)) {
           tud_cdc_rx_wanted_cb(itf, p_cdc->wanted_char);
         }
       }
     }

     // invoke receive callback (if there is still data)
     if (tud_cdc_rx_cb && !tu_fifo_empty(&p_cdc->rx_ff)) {
       tud_cdc_rx_cb(itf);
     }

     // prepare for OUT transaction
     _prep_out_transaction(itf);
   }

   // Data sent to host, we continue to fetch from tx fifo to send.
   // Note: This will cause incorrect baudrate set in line coding.
   //       Though maybe the baudrate is not really important !!!
   if (ep_addr == p_cdc->ep_in) {
     // invoke transmit callback to possibly refill tx fifo
     if (tud_cdc_tx_complete_cb) {
       tud_cdc_tx_complete_cb(itf);
     }

     if (0 == tud_cdc_n_write_flush(itf)) {
       // If there is no data left, a ZLP should be sent if
       // xferred_bytes is multiple of EP Packet size and not zero
       if (!tu_fifo_count(&p_cdc->tx_ff) && xferred_bytes && (0 == (xferred_bytes & (BULK_PACKET_SIZE - 1)))) {
         if (usbd_edpt_claim(rhport, p_cdc->ep_in)) {
           usbd_edpt_xfer(rhport, p_cdc->ep_in, NULL, 0);
         }
       }
     }
   }

   // nothing to do with notif endpoint for now

   return true;
 }

 #endif
	/*
	* The MIT License (MIT)
	*
	* Copyright (c) 2019 Ha Thach (tinyusb.org)
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to deal
	* in the Software without restriction, including without limitation the rights
	* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	* copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	* THE SOFTWARE.
	*
	* This file is part of the TinyUSB stack.
	*/

	#include "tusb_option.h"

	#if (CFG_TUD_ENABLED && CFG_TUD_CDC)

	#include "device/usbd.h"
	#include "device/usbd_pvt.h"

	#include "cdc_device.h"

	// Level where CFG_TUSB_DEBUG must be at least for this driver is logged
	#ifndef CFG_TUD_CDC_LOG_LEVEL
	#define CFG_TUD_CDC_LOG_LEVEL CFG_TUD_LOG_LEVEL
	#endif

	#define TU_LOG_DRV(...) TU_LOG(CFG_TUD_CDC_LOG_LEVEL, __VA_ARGS__)

	//--------------------------------------------------------------------+
	// MACRO CONSTANT TYPEDEF
	//--------------------------------------------------------------------+
	#define BULK_PACKET_SIZE (TUD_OPT_HIGH_SPEED ? 512 : 64)

	typedef struct {
	uint8_t itf_num;
	uint8_t ep_notif;
	uint8_t ep_in;
	uint8_t ep_out;

	// Bit 0: DTR (Data Terminal Ready), Bit 1: RTS (Request to Send)
	uint8_t line_state;

	/------------- From this point, data is not cleared by bus reset -------------/
	char wanted_char;
	TU_ATTR_ALIGNED(4) cdc_line_coding_t line_coding;

	// FIFO
	tu_fifo_t rx_ff;
	tu_fifo_t tx_ff;

	uint8_t rx_ff_buf[CFG_TUD_CDC_RX_BUFSIZE];
	uint8_t tx_ff_buf[CFG_TUD_CDC_TX_BUFSIZE];

	OSAL_MUTEX_DEF(rx_ff_mutex);
	OSAL_MUTEX_DEF(tx_ff_mutex);
	} cdcd_interface_t;

	#define ITF_MEM_RESET_SIZE offsetof(cdcd_interface_t, wanted_char)

	typedef struct {
	TUD_EPBUF_DEF(epout, CFG_TUD_CDC_EP_BUFSIZE);
	TUD_EPBUF_DEF(epin, CFG_TUD_CDC_EP_BUFSIZE);
	} cdcd_epbuf_t;

	//--------------------------------------------------------------------+
	// INTERNAL OBJECT & FUNCTION DECLARATION
	//--------------------------------------------------------------------+
	static cdcd_interface_t _cdcd_itf[CFG_TUD_CDC];
	CFG_TUD_MEM_SECTION static cdcd_epbuf_t _cdcd_epbuf[CFG_TUD_CDC];

	static tud_cdc_configure_fifo_t _cdcd_fifo_cfg;

	static bool _prep_out_transaction(uint8_t itf) {
	const uint8_t rhport = 0;
	cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
	cdcd_epbuf_t* p_epbuf = &_cdcd_epbuf[itf];

	// Skip if usb is not ready yet
	TU_VERIFY(tud_ready() && p_cdc->ep_out);

	uint16_t available = tu_fifo_remaining(&p_cdc->rx_ff);

	// Prepare for incoming data but only allow what we can store in the ring buffer.
	// TODO Actually we can still carry out the transfer, keeping count of received bytes
	// and slowly move it to the FIFO when read().
	// This pre-check reduces endpoint claiming
	TU_VERIFY(available >= CFG_TUD_CDC_EP_BUFSIZE);

	// claim endpoint
	TU_VERIFY(usbd_edpt_claim(rhport, p_cdc->ep_out));

	// fifo can be changed before endpoint is claimed
	available = tu_fifo_remaining(&p_cdc->rx_ff);

	if (available >= CFG_TUD_CDC_EP_BUFSIZE) {
	return usbd_edpt_xfer(rhport, p_cdc->ep_out, p_epbuf->epout, CFG_TUD_CDC_EP_BUFSIZE);
	} else {
	// Release endpoint since we don't make any transfer
	usbd_edpt_release(rhport, p_cdc->ep_out);
	return false;
	}
	}

	//--------------------------------------------------------------------+
	// APPLICATION API
	//--------------------------------------------------------------------+

	bool tud_cdc_configure_fifo(const tud_cdc_configure_fifo_t* cfg) {
	TU_VERIFY(cfg);
	_cdcd_fifo_cfg = (*cfg);
	return true;
	}

	bool tud_cdc_n_ready(uint8_t itf) {
	return tud_ready() && _cdcd_itf[itf].ep_in != 0 && _cdcd_itf[itf].ep_out != 0;
	}

	bool tud_cdc_n_connected(uint8_t itf) {
	// DTR (bit 0) active is considered as connected
	return tud_ready() && tu_bit_test(_cdcd_itf[itf].line_state, 0);
	}

	uint8_t tud_cdc_n_get_line_state(uint8_t itf) {
	return _cdcd_itf[itf].line_state;
	}

	void tud_cdc_n_get_line_coding(uint8_t itf, cdc_line_coding_t* coding) {
	(*coding) = _cdcd_itf[itf].line_coding;
	}

	void tud_cdc_n_set_wanted_char(uint8_t itf, char wanted) {
	_cdcd_itf[itf].wanted_char = wanted;
	}

	//--------------------------------------------------------------------+
	// READ API
	//--------------------------------------------------------------------+
	uint32_t tud_cdc_n_available(uint8_t itf) {
	return tu_fifo_count(&_cdcd_itf[itf].rx_ff);
	}

	uint32_t tud_cdc_n_read(uint8_t itf, void* buffer, uint32_t bufsize) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
	uint32_t num_read = tu_fifo_read_n(&p_cdc->rx_ff, buffer, (uint16_t) TU_MIN(bufsize, UINT16_MAX));
	_prep_out_transaction(itf);
	return num_read;
	}

	bool tud_cdc_n_peek(uint8_t itf, uint8_t* chr) {
	return tu_fifo_peek(&_cdcd_itf[itf].rx_ff, chr);
	}

	void tud_cdc_n_read_flush(uint8_t itf) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
	tu_fifo_clear(&p_cdc->rx_ff);
	_prep_out_transaction(itf);
	}

	//--------------------------------------------------------------------+
	// WRITE API
	//--------------------------------------------------------------------+
	uint32_t tud_cdc_n_write(uint8_t itf, const void* buffer, uint32_t bufsize) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
	uint16_t ret = tu_fifo_write_n(&p_cdc->tx_ff, buffer, (uint16_t) TU_MIN(bufsize, UINT16_MAX));

	// flush if queue more than packet size
	if (tu_fifo_count(&p_cdc->tx_ff) >= BULK_PACKET_SIZE
	#if CFG_TUD_CDC_TX_BUFSIZE < BULK_PACKET_SIZE
	\|\| tu_fifo_full(&p_cdc->tx_ff) // check full if fifo size is less than packet size
	#endif
	) {
	tud_cdc_n_write_flush(itf);
	}

	return ret;
	}

	uint32_t tud_cdc_n_write_flush(uint8_t itf) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[itf];
	cdcd_epbuf_t* p_epbuf = &_cdcd_epbuf[itf];

	// Skip if usb is not ready yet
	TU_VERIFY(tud_ready(), 0);

	// No data to send
	if (!tu_fifo_count(&p_cdc->tx_ff)) {
	return 0;
	}

	const uint8_t rhport = 0;

	// Claim the endpoint
	TU_VERIFY(usbd_edpt_claim(rhport, p_cdc->ep_in), 0);

	// Pull data from FIFO
	const uint16_t count = tu_fifo_read_n(&p_cdc->tx_ff, p_epbuf->epin, CFG_TUD_CDC_EP_BUFSIZE);

	if (count) {
	TU_ASSERT(usbd_edpt_xfer(rhport, p_cdc->ep_in, p_epbuf->epin, count), 0);
	return count;
	} else {
	// Release endpoint since we don't make any transfer
	// Note: data is dropped if terminal is not connected
	usbd_edpt_release(rhport, p_cdc->ep_in);
	return 0;
	}
	}

	uint32_t tud_cdc_n_write_available(uint8_t itf) {
	return tu_fifo_remaining(&_cdcd_itf[itf].tx_ff);
	}

	bool tud_cdc_n_write_clear(uint8_t itf) {
	return tu_fifo_clear(&_cdcd_itf[itf].tx_ff);
	}

	//--------------------------------------------------------------------+
	// USBD Driver API
	//--------------------------------------------------------------------+
	void cdcd_init(void) {
	tu_memclr(_cdcd_itf, sizeof(_cdcd_itf));
	tu_memclr(&_cdcd_fifo_cfg, sizeof(_cdcd_fifo_cfg));

	for (uint8_t i = 0; i < CFG_TUD_CDC; i++) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[i];

	p_cdc->wanted_char = (char) -1;

	// default line coding is : stop bit = 1, parity = none, data bits = 8
	p_cdc->line_coding.bit_rate = 115200;
	p_cdc->line_coding.stop_bits = 0;
	p_cdc->line_coding.parity = 0;
	p_cdc->line_coding.data_bits = 8;

	// Config RX fifo
	tu_fifo_config(&p_cdc->rx_ff, p_cdc->rx_ff_buf, TU_ARRAY_SIZE(p_cdc->rx_ff_buf), 1, false);

	// Config TX fifo as overwritable at initialization and will be changed to non-overwritable
	// if terminal supports DTR bit. Without DTR we do not know if data is actually polled by terminal.
	// In this way, the most current data is prioritized.
	tu_fifo_config(&p_cdc->tx_ff, p_cdc->tx_ff_buf, TU_ARRAY_SIZE(p_cdc->tx_ff_buf), 1, true);

	#if OSAL_MUTEX_REQUIRED
	osal_mutex_t mutex_rd = osal_mutex_create(&p_cdc->rx_ff_mutex);
	osal_mutex_t mutex_wr = osal_mutex_create(&p_cdc->tx_ff_mutex);
	TU_ASSERT(mutex_rd != NULL && mutex_wr != NULL, );

	tu_fifo_config_mutex(&p_cdc->rx_ff, NULL, mutex_rd);
	tu_fifo_config_mutex(&p_cdc->tx_ff, mutex_wr, NULL);
	#endif
	}
	}

	bool cdcd_deinit(void) {
	#if OSAL_MUTEX_REQUIRED
	for(uint8_t i=0; i<CFG_TUD_CDC; i++) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[i];
	osal_mutex_t mutex_rd = p_cdc->rx_ff.mutex_rd;
	osal_mutex_t mutex_wr = p_cdc->tx_ff.mutex_wr;

	if (mutex_rd) {
	osal_mutex_delete(mutex_rd);
	tu_fifo_config_mutex(&p_cdc->rx_ff, NULL, NULL);
	}

	if (mutex_wr) {
	osal_mutex_delete(mutex_wr);
	tu_fifo_config_mutex(&p_cdc->tx_ff, NULL, NULL);
	}
	}
	#endif

	return true;
	}

	void cdcd_reset(uint8_t rhport) {
	(void) rhport;

	for (uint8_t i = 0; i < CFG_TUD_CDC; i++) {
	cdcd_interface_t* p_cdc = &_cdcd_itf[i];

	tu_memclr(p_cdc, ITF_MEM_RESET_SIZE);
	if (!_cdcd_fifo_cfg.rx_persistent) {
	tu_fifo_clear(&p_cdc->rx_ff);
	}
	if (!_cdcd_fifo_cfg.tx_persistent) {
	tu_fifo_clear(&p_cdc->tx_ff);
	}
	tu_fifo_set_overwritable(&p_cdc->tx_ff, true);
	}
	}

	uint16_t cdcd_open(uint8_t rhport, const tusb_desc_interface_t* itf_desc, uint16_t max_len) {
	// Only support ACM subclass
	TU_VERIFY( TUSB_CLASS_CDC == itf_desc->bInterfaceClass &&
	CDC_COMM_SUBCLASS_ABSTRACT_CONTROL_MODEL == itf_desc->bInterfaceSubClass, 0);

	// Find available interface
	cdcd_interface_t* p_cdc;
	uint8_t cdc_id;
	for (cdc_id = 0; cdc_id < CFG_TUD_CDC; cdc_id++) {
	p_cdc = &_cdcd_itf[cdc_id];
	if (p_cdc->ep_in == 0) {
	break;
	}
	}
	TU_ASSERT(cdc_id < CFG_TUD_CDC, 0);

	//------------- Control Interface -------------//
	p_cdc->itf_num = itf_desc->bInterfaceNumber;

	uint16_t drv_len = sizeof(tusb_desc_interface_t);
	const uint8_t* p_desc = tu_desc_next(itf_desc);

	// Communication Functional Descriptors
	while (TUSB_DESC_CS_INTERFACE == tu_desc_type(p_desc) && drv_len <= max_len) {
	drv_len += tu_desc_len(p_desc);
	p_desc = tu_desc_next(p_desc);
	}

	if (TUSB_DESC_ENDPOINT == tu_desc_type(p_desc)) {
	// notification endpoint
	const tusb_desc_endpoint_t* desc_ep = (const tusb_desc_endpoint_t*) p_desc;

	TU_ASSERT(usbd_edpt_open(rhport, desc_ep), 0);
	p_cdc->ep_notif = desc_ep->bEndpointAddress;

	drv_len += tu_desc_len(p_desc);
	p_desc = tu_desc_next(p_desc);
	}

	//------------- Data Interface (if any) -------------//
	if ((TUSB_DESC_INTERFACE == tu_desc_type(p_desc)) &&
	(TUSB_CLASS_CDC_DATA == ((const tusb_desc_interface_t*) p_desc)->bInterfaceClass)) {
	// next to endpoint descriptor
	drv_len += tu_desc_len(p_desc);
	p_desc = tu_desc_next(p_desc);

	// Open endpoint pair
	TU_ASSERT(usbd_open_edpt_pair(rhport, p_desc, 2, TUSB_XFER_BULK, &p_cdc->ep_out, &p_cdc->ep_in), 0);

	drv_len += 2 * sizeof(tusb_desc_endpoint_t);
	}

	// Prepare for incoming data
	_prep_out_transaction(cdc_id);

	return drv_len;
	}

	// Invoked when a control transfer occurred on an interface of this class
	// Driver response accordingly to the request and the transfer stage (setup/data/ack)
	// return false to stall control endpoint (e.g unsupported request)
	bool cdcd_control_xfer_cb(uint8_t rhport, uint8_t stage, const tusb_control_request_t* request) {
	// Handle class request only
	TU_VERIFY(request->bmRequestType_bit.type == TUSB_REQ_TYPE_CLASS);

	uint8_t itf;
	cdcd_interface_t* p_cdc;

	// Identify which interface to use
	for (itf = 0; itf < CFG_TUD_CDC; itf++) {
	p_cdc = &_cdcd_itf[itf];
	if (p_cdc->itf_num == request->wIndex) {
	break;
	}
	}
	TU_VERIFY(itf < CFG_TUD_CDC);

	switch (request->bRequest) {
	case CDC_REQUEST_SET_LINE_CODING:
	if (stage == CONTROL_STAGE_SETUP) {
	TU_LOG_DRV(" Set Line Coding\r\n");
	tud_control_xfer(rhport, request, &p_cdc->line_coding, sizeof(cdc_line_coding_t));
	} else if (stage == CONTROL_STAGE_ACK) {
	if (tud_cdc_line_coding_cb) {
	tud_cdc_line_coding_cb(itf, &p_cdc->line_coding);
	}
	}
	break;

	case CDC_REQUEST_GET_LINE_CODING:
	if (stage == CONTROL_STAGE_SETUP) {
	TU_LOG_DRV(" Get Line Coding\r\n");
	tud_control_xfer(rhport, request, &p_cdc->line_coding, sizeof(cdc_line_coding_t));
	}
	break;

	case CDC_REQUEST_SET_CONTROL_LINE_STATE:
	if (stage == CONTROL_STAGE_SETUP) {
	tud_control_status(rhport, request);
	} else if (stage == CONTROL_STAGE_ACK) {
	// CDC PSTN v1.2 section 6.3.12
	// Bit 0: Indicates if DTE is present or not.
	// This signal corresponds to V.24 signal 108/2 and RS-232 signal DTR (Data Terminal Ready)
	// Bit 1: Carrier control for half-duplex modems.
	// This signal corresponds to V.24 signal 105 and RS-232 signal RTS (Request to Send)
	bool const dtr = tu_bit_test(request->wValue, 0);
	bool const rts = tu_bit_test(request->wValue, 1);

	p_cdc->line_state = (uint8_t) request->wValue;

	// Disable fifo overwriting if DTR bit is set
	tu_fifo_set_overwritable(&p_cdc->tx_ff, !dtr);

	TU_LOG_DRV(" Set Control Line State: DTR = %d, RTS = %d\r\n", dtr, rts);

	// Invoke callback
	if (tud_cdc_line_state_cb) {
	tud_cdc_line_state_cb(itf, dtr, rts);
	}
	}
	break;

	case CDC_REQUEST_SEND_BREAK:
	if (stage == CONTROL_STAGE_SETUP) {
	tud_control_status(rhport, request);
	} else if (stage == CONTROL_STAGE_ACK) {
	TU_LOG_DRV(" Send Break\r\n");
	if (tud_cdc_send_break_cb) {
	tud_cdc_send_break_cb(itf, request->wValue);
	}
	}
	break;

	default:
	return false; // stall unsupported request
	}

	return true;
	}

	bool cdcd_xfer_cb(uint8_t rhport, uint8_t ep_addr, xfer_result_t result, uint32_t xferred_bytes) {
	(void) result;

	uint8_t itf;
	cdcd_interface_t* p_cdc;

	// Identify which interface to use
	for (itf = 0; itf < CFG_TUD_CDC; itf++) {
	p_cdc = &_cdcd_itf[itf];
	if ((ep_addr == p_cdc->ep_out) \|\| (ep_addr == p_cdc->ep_in)) {
	break;
	}
	}
	TU_ASSERT(itf < CFG_TUD_CDC);
	cdcd_epbuf_t* p_epbuf = &_cdcd_epbuf[itf];

	// Received new data
	if (ep_addr == p_cdc->ep_out) {
	tu_fifo_write_n(&p_cdc->rx_ff, p_epbuf->epout, (uint16_t) xferred_bytes);

	// Check for wanted char and invoke callback if needed
	if (tud_cdc_rx_wanted_cb && (((signed char) p_cdc->wanted_char) != -1)) {
	for (uint32_t i = 0; i < xferred_bytes; i++) {
	if ((p_cdc->wanted_char == p_epbuf->epout[i]) && !tu_fifo_empty(&p_cdc->rx_ff)) {
	tud_cdc_rx_wanted_cb(itf, p_cdc->wanted_char);
	}
	}
	}

	// invoke receive callback (if there is still data)
	if (tud_cdc_rx_cb && !tu_fifo_empty(&p_cdc->rx_ff)) {
	tud_cdc_rx_cb(itf);
	}

	// prepare for OUT transaction
	_prep_out_transaction(itf);
	}

	// Data sent to host, we continue to fetch from tx fifo to send.
	// Note: This will cause incorrect baudrate set in line coding.
	// Though maybe the baudrate is not really important !!!
	if (ep_addr == p_cdc->ep_in) {
	// invoke transmit callback to possibly refill tx fifo
	if (tud_cdc_tx_complete_cb) {
	tud_cdc_tx_complete_cb(itf);
	}

	if (0 == tud_cdc_n_write_flush(itf)) {
	// If there is no data left, a ZLP should be sent if
	// xferred_bytes is multiple of EP Packet size and not zero
	if (!tu_fifo_count(&p_cdc->tx_ff) && xferred_bytes && (0 == (xferred_bytes & (BULK_PACKET_SIZE - 1)))) {
	if (usbd_edpt_claim(rhport, p_cdc->ep_in)) {
	usbd_edpt_xfer(rhport, p_cdc->ep_in, NULL, 0);
	}
	}
	}
	}

	// nothing to do with notif endpoint for now

	return true;
	}

	#endif