/* LUFA Library Copyright (C) Dean Camera, 2010. dean [at] fourwalledcubicle [dot] com www.fourwalledcubicle.com */ /* Copyright 2010 Dean Camera (dean [at] fourwalledcubicle [dot] com) Permission to use, copy, modify, distribute, and sell this software and its documentation for any purpose is hereby granted without fee, provided that the above copyright notice appear in all copies and that both that the copyright notice and this permission notice and warranty disclaimer appear in supporting documentation, and that the name of the author not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. The author disclaim all warranties with regard to this software, including all implied warranties of merchantability and fitness. In no event shall the author be liable for any special, indirect or consequential damages or any damages whatsoever resulting from loss of use, data or profits, whether in an action of contract, negligence or other tortious action, arising out of or in connection with the use or performance of this software. */ /** \file * * Main source file for the Arduino-usbserial project. This file contains the main tasks of * the project and is responsible for the initial application hardware configuration. */ #include "Arduino-usbserial.h" /** Circular buffer to hold data from the host before it is sent to the device via the serial port. */ RingBuff_t USBtoUSART_Buffer; /** Circular buffer to hold data from the serial port before it is sent to the host. */ RingBuff_t USARTtoUSB_Buffer; /** Pulse generation counters to keep track of the number of milliseconds remaining for each pulse type */ volatile struct { uint8_t TxLEDPulse; /**< Milliseconds remaining for data Tx LED pulse */ uint8_t RxLEDPulse; /**< Milliseconds remaining for data Rx LED pulse */ uint8_t PingPongLEDPulse; /**< Milliseconds remaining for enumeration Tx/Rx ping-pong LED pulse */ } PulseMSRemaining; /** LUFA CDC Class driver interface configuration and state information. This structure is * passed to all CDC Class driver functions, so that multiple instances of the same class * within a device can be differentiated from one another. */ USB_ClassInfo_CDC_Device_t VirtualSerial_CDC_Interface = { .Config = { .ControlInterfaceNumber = 0, .DataINEndpointNumber = CDC_TX_EPNUM, .DataINEndpointSize = CDC_TXRX_EPSIZE, .DataINEndpointDoubleBank = false, .DataOUTEndpointNumber = CDC_RX_EPNUM, .DataOUTEndpointSize = CDC_TXRX_EPSIZE, .DataOUTEndpointDoubleBank = false, .NotificationEndpointNumber = CDC_NOTIFICATION_EPNUM, .NotificationEndpointSize = CDC_NOTIFICATION_EPSIZE, .NotificationEndpointDoubleBank = false, }, }; /** Main program entry point. This routine contains the overall program flow, including initial * setup of all components and the main program loop. */ int main(void) { SetupHardware(); RingBuffer_InitBuffer(&USBtoUSART_Buffer); RingBuffer_InitBuffer(&USARTtoUSB_Buffer); sei(); for (;;) { /* Read bytes from the USB OUT endpoint into the USART transmit buffer */ int16_t ReceivedByte = CDC_Device_ReceiveByte(&VirtualSerial_CDC_Interface); if (!(ReceivedByte < 0) && !(RingBuffer_IsFull(&USBtoUSART_Buffer))) RingBuffer_Insert(&USBtoUSART_Buffer, ReceivedByte); /* Check if the UART receive buffer flush timer has expired or the buffer is nearly full */ RingBuff_Count_t BufferCount = RingBuffer_GetCount(&USARTtoUSB_Buffer); if ((TIFR0 & (1 << TOV0)) || (BufferCount > BUFFER_NEARLY_FULL)) { TIFR0 |= (1 << TOV0); if (USARTtoUSB_Buffer.Count) { LEDs_TurnOnLEDs(LEDMASK_TX); PulseMSRemaining.TxLEDPulse = TX_RX_LED_PULSE_MS; } /* Read bytes from the USART receive buffer into the USB IN endpoint */ while (BufferCount--) CDC_Device_SendByte(&VirtualSerial_CDC_Interface, RingBuffer_Remove(&USARTtoUSB_Buffer)); /* Turn off TX LED(s) once the TX pulse period has elapsed */ if (PulseMSRemaining.TxLEDPulse && !(--PulseMSRemaining.TxLEDPulse)) LEDs_TurnOffLEDs(LEDMASK_TX); /* Turn off RX LED(s) once the RX pulse period has elapsed */ if (PulseMSRemaining.RxLEDPulse && !(--PulseMSRemaining.RxLEDPulse)) LEDs_TurnOffLEDs(LEDMASK_RX); } /* Load the next byte from the USART transmit buffer into the USART */ if (!(RingBuffer_IsEmpty(&USBtoUSART_Buffer))) { Serial_TxByte(RingBuffer_Remove(&USBtoUSART_Buffer)); LEDs_TurnOnLEDs(LEDMASK_RX); PulseMSRemaining.RxLEDPulse = TX_RX_LED_PULSE_MS; } CDC_Device_USBTask(&VirtualSerial_CDC_Interface); USB_USBTask(); } } /** Configures the board hardware and chip peripherals for the demo's functionality. */ void SetupHardware(void) { /* Disable watchdog if enabled by bootloader/fuses */ MCUSR &= ~(1 << WDRF); wdt_disable(); /* Hardware Initialization */ Serial_Init(9600, false); LEDs_Init(); USB_Init(); /* Start the flush timer so that overflows occur rapidly to push received bytes to the USB interface */ TCCR0B = (1 << CS02); /* Pull target /RESET line high */ AVR_RESET_LINE_PORT |= AVR_RESET_LINE_MASK; AVR_RESET_LINE_DDR |= AVR_RESET_LINE_MASK; } /** Event handler for the library USB Configuration Changed event. */ void EVENT_USB_Device_ConfigurationChanged(void) { if (!(CDC_Device_ConfigureEndpoints(&VirtualSerial_CDC_Interface))) ; } /** Event handler for the library USB Unhandled Control Request event. */ void EVENT_USB_Device_UnhandledControlRequest(void) { CDC_Device_ProcessControlRequest(&VirtualSerial_CDC_Interface); } /** Event handler for the CDC Class driver Line Encoding Changed event. * * \param[in] CDCInterfaceInfo Pointer to the CDC class interface configuration structure being referenced */ void EVENT_CDC_Device_LineEncodingChanged(USB_ClassInfo_CDC_Device_t* const CDCInterfaceInfo) { uint8_t ConfigMask = 0; switch (CDCInterfaceInfo->State.LineEncoding.ParityType) { case CDC_PARITY_Odd: ConfigMask = ((1 << UPM11) | (1 << UPM10)); break; case CDC_PARITY_Even: ConfigMask = (1 << UPM11); break; } if (CDCInterfaceInfo->State.LineEncoding.CharFormat == CDC_LINEENCODING_TwoStopBits) ConfigMask |= (1 << USBS1); switch (CDCInterfaceInfo->State.LineEncoding.DataBits) { case 6: ConfigMask |= (1 << UCSZ10); break; case 7: ConfigMask |= (1 << UCSZ11); break; case 8: ConfigMask |= ((1 << UCSZ11) | (1 << UCSZ10)); break; } /* Must turn off USART before reconfiguring it, otherwise incorrect operation may occur */ UCSR1B = 0; UCSR1A = 0; UCSR1C = 0; /* Special case 57600 baud for compatibility with the ATmega328 bootloader. */ UCSR1A = (CDCInterfaceInfo->State.LineEncoding.BaudRateBPS == 57600) ? 0 : (1 << U2X1); UCSR1B = ((1 << RXCIE1) | (1 << TXEN1) | (1 << RXEN1)); UCSR1C = ConfigMask; UBRR1 = (CDCInterfaceInfo->State.LineEncoding.BaudRateBPS == 57600) ? SERIAL_UBBRVAL(CDCInterfaceInfo->State.LineEncoding.BaudRateBPS) : SERIAL_2X_UBBRVAL(CDCInterfaceInfo->State.LineEncoding.BaudRateBPS); } /** ISR to manage the reception of data from the serial port, placing received bytes into a circular buffer * for later transmission to the host. */ ISR(USART1_RX_vect, ISR_BLOCK) { uint8_t ReceivedByte = UDR1; if (USB_DeviceState == DEVICE_STATE_Configured) RingBuffer_Insert(&USARTtoUSB_Buffer, ReceivedByte); } /** Event handler for the CDC Class driver Host-to-Device Line Encoding Changed event. * * \param[in] CDCInterfaceInfo Pointer to the CDC class interface configuration structure being referenced */ void EVENT_CDC_Device_ControLineStateChanged(USB_ClassInfo_CDC_Device_t* const CDCInterfaceInfo) { bool CurrentDTRState = (CDCInterfaceInfo->State.ControlLineStates.HostToDevice & CDC_CONTROL_LINE_OUT_DTR); if (CurrentDTRState) { AVR_RESET_LINE_PORT &= ~AVR_RESET_LINE_MASK; } else { AVR_RESET_LINE_PORT |= AVR_RESET_LINE_MASK; } }