=========== Arduino Due =========== This documentation discusses issues unique to NuttX configurations for the Arduino DUE board featuring the Atmel ATSAM3X8E MCU running at 84 MHz. .. note:: If found that newer Arduino Due board differ from the older boards mine: Mine has the 32.768 slow clock crystal and associated caps installed. The newer boards do not. This can cause a hang in the SAM startup code where it waits for the slow crystal input to lock on. Options: 1. Solder a 32.768 KHz crystal and associated caps on board or, 2. Disable the function ``sam_setupsupc()`` in ``sam_clockconfig.c`` Supported Shields ================= * ITEAD 2.4" TFT with Touch, Arduino Shield 1.0 PIO Pin Usage ============= PORTA ----- .. csv-table:: :header: PIO,SIGNAL,CONN,PIN PA0,CANTX0,ADCH,8 PA1,CANRX0,ACDH,7 PA2,AD7,ADCL,8 PA3,AD6,ADCL,7 PA4,AD5,ADCL,6 PA5,EEXTINT,ETH ,8 PA6,AD4,ADCL,5 PA7,PIN31,XIO ,12 PA8,[U]RX,PWML,1 PA9,[U]TX,PWML,2 PA10,RXD2,COMM,6 PA11,TXD2,COMM,5 PA12,RXD1,COMM,4 PA13,TXD1,COMM,3 PA14,PIN23,XIO ,4 PA15,PIN24,XIO ,5 PA16,AD0,ADCL,1 PA17,SDA1,PWMH,9 PA18,SCL1,PWMH,10 PA19,PIN42,XIO ,23 PA20,PIN43,XIO ,24 PA21,TXL,TX,YELLOW LED PA22,AD3,ADCL,4 PA23,AD2,ADCL,3 PA24,AD1,ADCL,2 PA25,MISO,SPI,1 PA26,MOSI,SPI,4 PA27,SPCK,SPI,3 PA28,SS0/PWM10,(ETH) PWML,10 PA29,SS1/PWM4 ,(SD), PA30,N/A,N/A, PA31,N/A,N/A, PORTB ----- .. csv-table:: :header: PIO,SIGNAL,CONN,PIN PB0,ETX_CLK,ETH,1 PB1,ETX_EN,ETH,3 PB2,ETXD0,ETH,5 PB3,ETXD1,ETH,7 PB4,ERX_DV,ETH,10 PB5,ERXD0,ETH,9 PB6,ERXD1,ETH,11 PB7,ERX_ER,ETH,13 PB8,EMDC,ETH,14 PB9,EMDIO,ETH,12 PB10,UOTGVBO,Vbus power, PB11,UOTGID ,USB1,4 PB12,SDA0-3 ,COMM,7 PB13,SCL0-3 ,COMM,8 PB14,CANTX1/IO ,XIO ,34 PB15,DAC0(CANRX1),ADCH,5 PB16,DAC1,ADCH,6 PB17,AD8,ADCH,1 PB18,AD9,ADCH,2 PB19,AD10,ADCH,3 PB20,AD11(TXD3),ADCH,4 PB21,AD14(RXD3),XIO,33 PB22,N/C,N/A, PB23,SS3,???, PB24,N/C,N/A, PB25,PWM2,PWML,3 PB26,PIN22,???, PB27,PWM13,PWMH,6 PB28,JTAG_TCK,JTAG,4 PB29,JTAG_TDI,JTAG,8 PB30,JTAG_TDO,JTAG,6 PB31,JTAG_TMS,JTAG,2 PORTC ----- .. csv-table:: :header: PIO,SIGNAL,CONN,PIN PC0 , ERASE, N/A, PC1 , PIN33, XIO, 14 PC2 , PIN34, XIO, 15 PC3 , PIN35, XIO, 16 PC4 , PIN36, XIO, 17 PC5 , PIN37, XIO, 18 PC6 , PIN38, XIO, 19 PC7 , PIN39, XIO, 20 PC8 , PIN40, XIO, 21 PC9 , PIN41, XIO, 22 PC10, N/C , N/A, PC11, N/C , N/A, PC12, PIN51, XIO, 32 PC13, PIN50, XIO, 31 PC14, PIN49, XIO, 30 PC15, PIN48, XIO, 29 PC16, PIN47, XIO, 28 PC17, PIN46, XIO, 27 PC18, PIN45, XIO, 26 PC19, PIN44, XIO, 25 PC20, N/C , N/A, PC21, PWM9 , PWM, 2 PC22, PWM8 , PWM, 1 PC23, PWM7 , PWM, 8 PC24, PWM6 , PWM, 7 PC25, PWM5 , PWM, 6 PC26, SS1/PWM4, PWM, 10 (there are two) PC27, N/C , N/A, PC28, PWM3, PWML,4 PC29, SS0/PWM10, ???,(there are two) PC30, RXL, RX,YELLOW LED PC31, N/A, N/A, PORTD ----- .. csv-table:: :header: PIO,SIGNAL,CONN,PIN PD0 , PIN25, XIO ,6 PD1 , PIN26, XIO ,7 PD2 , PIN27, XIO ,8 PD3 , PIN28, XIO ,9 PD4 , TXD0, COMM,1 PD5 , RXD0, COMM,2 PD6 , PIN29, XIO ,10 PD7 , PWM11, PWMH,4 PD8 , PWM12, PWMH,5 PD9 , PIN30, XIO ,11 PD10, PIN32, XIO ,13 PD11, N/A, N/A , PD12, N/A, N/A , PD13, N/A, N/A , PD14, N/A, N/A , PD15, N/A, N/A , PD16, N/A, N/A , PD17, N/A, N/A , PD18, N/A, N/A , PD19, N/A, N/A , PD20, N/A, N/A , PD21, N/A, N/A , PD22, N/A, N/A , PD23, N/A, N/A , PD24, N/A, N/A , PD25, N/A, N/A , PD26, N/A, N/A , PD27, N/A, N/A , PD28, N/A, N/A , PD29, N/A, N/A , PD30, N/A, N/A , PD31, N/A, N/A , PORTE ----- .. csv-table:: :header: PIO,SIGNAL,CONN,PIN PE0 ,N/A,N/A PE1 ,N/A,N/A PE2 ,N/A,N/A PE3 ,N/A,N/A PE4 ,N/A,N/A PE5 ,N/A,N/A PE6 ,N/A,N/A PE7 ,N/A,N/A PE8 ,N/A,N/A PE9 ,N/A,N/A PE10,N/A,N/A PE11,N/A,N/A PE12,N/A,N/A PE13,N/A,N/A PE14,N/A,N/A PE15,N/A,N/A PE16,N/A,N/A PE17,N/A,N/A PE18,N/A,N/A PE19,N/A,N/A PE20,N/A,N/A PE21,N/A,N/A PE22,N/A,N/A PE23,N/A,N/A PE24,N/A,N/A PE25,N/A,N/A PE26,N/A,N/A PE27,N/A,N/A PE28,N/A,N/A PE29,N/A,N/A PE30,N/A,N/A PE31,N/A,N/A PORTF ----- .. csv-table:: :header: PIO,SIGNAL,CONN,PIN PF0 ,N/A,N/A PF1 ,N/A,N/A PF2 ,N/A,N/A PF3 ,N/A,N/A PF4 ,N/A,N/A PF5 ,N/A,N/A PF6 ,N/A,N/A PF7 ,N/A,N/A PF8 ,N/A,N/A PF9 ,N/A,N/A PF10,N/A,N/A PF11,N/A,N/A PF12,N/A,N/A PF13,N/A,N/A PF14,N/A,N/A PF15,N/A,N/A PF16,N/A,N/A PF17,N/A,N/A PF18,N/A,N/A PF19,N/A,N/A PF20,N/A,N/A PF21,N/A,N/A PF22,N/A,N/A PF23,N/A,N/A PF24,N/A,N/A PF25,N/A,N/A PF26,N/A,N/A PF27,N/A,N/A PF28,N/A,N/A PF29,N/A,N/A PF30,N/A,N/A PF31,N/A,N/A Rev 2 vs. Rev 3 =============== This port was performed on the Arduino Due Rev 2 board. NuttX users have reported issues with the serial port on his Arduino Due Rev 3 board. That problem was resolved as by configuring the UART0 RXD with a pull-up (see ``include/board.h``). That fix as well as any others that we may find will be enabled by selecting: ``CONFIG_ARDUINO_DUE_REV3=y`` ITEAD 2.4" TFT with Touch ========================= The Arduino 2.4" TFT Touch Shield is designed for all the Arduino compatible boards. It works in 3.3V voltage level. It can be directly plugged on the Arduino and other compatible boards. It will offer display, touch and storage functions for the Arduino board Features: 1. Compatible with 3.3/5V operation voltage level 2. Compatible with UTFT library 3. With SD Card Socket The Arduino 2.4" TFT Touch shield uses the S6D1121 controller , it supports 8-bit data interface. The touch IC is XPT2046. .. note:: When used with the ITEAD shield, the power from the USB connector seems to be inefficient (for example, I lose the USB connection when I insert an SD card). I recommend using a 7-12V power supply with the Arduino in this case. Connector --------- **PWMH** ========== ==== ====================== =========== ================ ============= ================== Due PIN GPIO FUNCTION SIGNAL ITHEAD PIN ITHEAD SIGNAL NOTES ========== ==== ====================== =========== ================ ============= ================== 10 SCL1 PA18 TWCK0/A20/WKUP9 SCL1 --- --- --- SCL not available 9 SDA1 PA17 TWD0SPCK0 SDA1 --- --- --- SDA not available 8 Aref --- --- AREF J2 pin 8 Vref N/C --- 7 GND --- --- GND J2 pin 7 GND --- --- 6 PWM13 PB27 SPI0_SPCK/A20/WKUP10 PWM13 J2 pin 6 D13 SD_SCK SCK, also LED "L", Pulled low 5 PWM12 PD8 A21/NANDALE/TIOB8 PWM12 J2 pin 5 D12 SD_MISO MISO not available 4 PWM11 PD7 A17/BA1/TIOA8 PWM11 J2 pin 4 D11 SD_MOSI MOSI not available, Pulled low 3 PWM10 PA28 SPI0_NPCS0/PCK2/WKUP11 SS0/PWM10 J2 pin 3 D10 SD_CS Pulled low on-board 2 PWM9 PC21 A0/NBS0/PWML4 PWM9 J2 pin 2 D9 Touch_Dout --- 1 PWM8 PC22 A1/PWML5 PWM8 J2 pin 1 D8 Touch_IRQ --- ========== ==== ====================== =========== ================ ============= ================== **PWML** ========== ==== ====================== =========== ================ ============= ================== Due PIN GPIO FUNCTION SIGNAL ITHEAD PIN ITHEAD SIGNAL NOTES ========== ==== ====================== =========== ================ ============= ================== 8 PWM7 PC23 A2/PWML6 PWM7 J3 pin 8 D7 DB15 --- 7 PWM6 PC24 A3/PWML7 PWM6 J3 pin 7 D6 DB14 --- 6 PWM5 PC25 A4/TIOA6 PWM5 J3 pin 6 D5 DB13 --- 5 PWM4 PC26 A5/TIOB6 SS1/PWM4 J3 pin 5 D4 DB12 --- 4 PWM3 PC28 A7/TIOA7 PWM3 J3 pin 4 D3 DB11 --- 3 PWM2 PB25 RTS0/TIOA0 PWM2 J3 pin 3 D2 DB10 --- 2 PWM1 PA9 UTXD/PWMH3 TX J3 pin 2 D1 DB9 UART0 TX 1 PWM0 PA8 URXD/PWMH0/WKUP4 RX J3 pin 1 D0 DB8 UART0 RX ========== ==== ====================== =========== ================ ============= ================== **POWER** ========== ==== ====================== ============ ================ ============= ================== Due PIN GPIO FUNCTION SIGNAL ITHEAD PIN ITHEAD SIGNAL NOTES ========== ==== ====================== ============ ================ ============= ================== 1 --- --- --- --- --- --- --- --- 2 IOref --- --- IOREF +3V3 --- --- --- --- 3 RESET --- --- MASTER_RESET J4 pin 1 RST --- --- 5 5V --- --- +5V J4 pin 2 3.3V --- --- 4 3.3V --- --- +3V3 J4 pin 3 5V --- --- 6 GND --- --- GND J4 pin 4 GND --- --- 7 GND --- --- GND J4 pin 5 GND --- --- 8 Vin --- --- VIN J4 pin 6 Vin --- --- ========== ==== ====================== ============ ================ ============= ================== **ADCL** ========== ==== ====================== =========== ================ ============= ================== Due PIN GPIO FUNCTION SIGNAL ITHEAD PIN ITHEAD SIGNAL NOTES ========== ==== ====================== =========== ================ ============= ================== 1 A0 PA16 SPCK1/TD/AD7 AD0 J1 pin 1 A0/D14 Touch_Din --- 2 A1 PA24 MCDA3/PCK1/AD6 AD1 J1 pin 2 A1/D15 Touch_CLK --- 3 A2 PA23 MCDA2/TCLK4/AD5 AD2 J1 pin 3 A2/D16 --- --- 4 A3 PA22 MCDA1/TCLK3/AD4 AD3 J1 pin 4 A3/D17 TFT_CS --- 5 A4 PA6 TIOB2/NCS0/AD3 AD4 J1 pin 5 A4/D18 TFT_WR --- 6 A5 PA4 TCLK1/NWAIT/AD2 AD5 J1 pin 6 A5/D19 TFT_RS --- 7 A6 PA3 TIOB1/PWMFI1/AD1/WKUP1 AD6 --- --- --- --- 8 A7 PA2 TIOA1/NANDRDY/AD0 AD7 --- --- --- --- ========== ==== ====================== =========== ================ ============= ================== .. note:: 1. It is not possible to use any of the SPI devices on the Shield unless a bit-bang SPI interface is used. This includes the touch controller a bit-bang SPI interface is used. This includes the touch controller and the SD card. 2. UART0 cannot be used. USARTs on the COMM connector should be available. 3. Parallel data is not contiguous in the PIO register 4. Touchcontroller /CS pin is connected to ground (always selected). 5. Either PA28 or PC29 may drive PWM10 6. The schematics I have do not agree with the documentation. The Touch IRQ and Dout pins are reversed in the Documentation (D9 an D8, respectively). I am assuming that the schematic is correct (and the schematic does seem to match up with what little I can see on the single visible side of the board). SD Interface ------------ ====== ========= ======== ========= ======== SD PIN SD SIGNAL PIN SIGNAL GPIO ====== ========= ======== ========= ======== 1 /CS J2 pin 3 D10 PA28 2 DI J2 pin 4 D11 PD7 3 GND --- --- --- 4 VCC --- --- --- 5 CLK J2 pin 6 D13 PB27 6 GND --- --- --- 7 DO J2 pin 5 D12 PD8 8 IRQ N/C --- --- 9 N/C --- --- --- 10 SW N/C --- --- 11 WP N/C --- --- 12 CD N/C --- --- 13 CD N/C --- --- 14 GND --- --- --- 15 GND --- --- --- 16 GND --- --- --- ====== ========= ======== ========= ======== .. note:: * The SD slot shares the pin with LED "L" so LED support must be disabled to use the MMC/SD card on the ITEAD shield. * Either PA28 or PC29 may drive D10 Touch Controller Interface -------------------------- =========== ============== ======== ========= ======== XPT2046 PIN XPT2046 SIGNAL PIN SIGNAL GPIO =========== ============== ======== ========= ======== 1 VCC --- --- --- 2 X+ --- --- --- 3 Y+ --- --- --- 4 X- --- --- --- 5 Y- --- --- --- 6 GND --- --- --- 7 IN3 N/C --- --- 8 IN4 N/C --- --- 9 VREF --- --- --- 10 VCC --- --- --- 11 IRQ J2 pin 2 D9 PC21 12 DOUT J2 pin 1 D8 PC22 13 BUSY N/C --- --- 14 DIN J1 pin 1 A0/D15 PA16 15 /CS --- --- --- 16 DCLK J1 pin 2 A1/D15 PA24 =========== ============== ======== ========= ======== .. note:: CS is connected to ground (XPT2046 is always selected) Buttons and LEDs ================ Buttons ------- There are no buttons on the Arduino Due board. LEDs ---- There are three user-controllable LEDs on board the Arduino Due board: .. csv-table:: :header: LED,COLOUR,GPIO L,Amber LED,PB27 TX,Yellow LED,PA21 RX,Yellow LED,PC30 LED L is connected to ground and can be illuminated by driving the PB27 output high. The TX and RX LEDs are pulled high and can be illuminated by driving the corresponding GPIO output to low. These LEDs are not used by the board port unless ``CONFIG_ARCH_LEDS`` is defined. In that case, the usage by the board port is defined in ``include/board.h`` and ``src/sam_leds.c``. The LEDs are used to encode OS-related events as follows: .. csv-table:: :header: SYMBOL,MEANING,L,TX,RX ``LED_STARTED`` ,NuttX has been started ,OFF ,OFF ,OFF ``LED_HEAPALLOCATE`` ,Heap has been allocated ,OFF ,OFF ,OFF ``LED_IRQSENABLED`` ,Interrupts enabled ,OFF ,OFF ,OFF ``LED_STACKCREATED`` ,Idle stack created ,ON ,OFF ,OFF ``LED_INIRQ`` ,In an interrupt ,N/C ,GLOW ,OFF ``LED_SIGNAL`` ,In a signal handler ,N/C ,GLOW ,OFF ``LED_ASSERTION`` ,An assertion failed ,N/C ,GLOW ,OFF ``LED_PANIC`` ,The system has crashed ,N/C ,N/C ,Blinking ``LED_IDLE`` ,MCU is is sleep mode ,N/A ,N/A ,N/A Thus if LED L is statically on, NuttX has successfully booted and is, apparently, running normally. If LED RX is glowing, then NuttX is handling interrupts (and also signals and assertions). If TX is flashing at approximately 2Hz, then a fatal error has been detected and the system has halted. Serial Consoles =============== The SAM3X has a UART and 4 USARTS. The Programming port uses a USB-to- serial chip connected to the first UART0 of the MCU (RX0 and TX0). The output from that port is visible using the Arduino tool. Any of UART and USART0-3 may be used as a serial console. By default, the UART is used as the serial console in all configurations. But that is easily changed by modifying the configuration as described under "Configurations" below. Here are the UART signals available on pins. Under signal name, the first column is the name on the schematic associated with the GPIO, the second comes from: http://arduino.cc/en/Hacking/PinMappingSAM3X, and the third is the name of the multiplexed SAM3X UART function from the data sheet. This is more than a little confusing. ===== ========== ============== =========== ========== =========== PIO DUE SCHEM. PIN MAPPING SAM3X DUE SCHEM. BOARD LABEL ===== ========== ============== =========== ========== =========== PA8 [U]RX RX0 UART0 URXD PWML 1 RX0<-0 PA9 [U]TX TX0 UART0 UTXD PWML 2 TX0->1 PD5 RXD0 RX3 USART3 RXD3 COMM 2 RX3 PD4 TXD0 TX3 USART3 TXD3 COMM 1 TX3 PA12 RXD1 RX2 USART1 RXD1 COMM 4 TX2 PA13 TXD1 TX2 USART1 TXD1 COMM 3 RX2 PA10 RXD2 RX1 USART0 RXD0 COMM 6 RX1 PA11 TXD2 TX1 USART0 TXD0 COMM 5 TX1 PB21 AD14(RXD3) Digital Pin 52 USART2 RXD2 XIO 33 33 PB20 AD11(TXD3) Analog In 11 USART2 TXD2 ADCH 4 A11 ===== ========== ============== =========== ========== =========== The outputs from these pins is 3.3V. You will need to connect RS232 transceiver to get the signals to RS232 levels (or connect to the USB virtual COM port in the case of UART0). Loading Code ============ .. note:: I believe that there have been significant changes to the more recent tool environment such that Bossac may no longer be usable. I don't know that for certain and perhaps someone with more knowledge of the tools than I could make this work. See the Flip'n'Clip SAM3X README file for additional information. Installing the Arduino USB Driver under Windows: ------------------------------------------------ 1. Download the Windows version of the Arduino software, not the 1.0.x release but the latest (1.5.x or later) that supports the Due. When the download finishes, unzip the downloaded file. In the current 1.8.x release, the Arduino Due support is not included in the base package but can be added by selecting the "Boards Manager" from the "Tools" menu. 2. Connect the Due to your computer with a USB cable via the Programming port. 3. The Windows driver installation should fail. 4. Open the Device Manager 5. Look for the listing named "Ports (COM & LPT)". You should see an open port named "Arduino Due Prog. Port". Right click and select "Update driver". 6. Select the "Browse my computer for Driver software" option. 7. Right click on the "Arduino Due Prog. Port" and choose "Update Driver Software". 8. Navigate to the folder with the Arduino IDE you downloaded and unzipped earlier. Locate and select the "Drivers" folder in the main Arduino folder (not the "FTDI USB Drivers" sub-directory). Loading NuttX to the Due Using Bossa ------------------------------------- Arduino uses BOSSA under the hood to load code and you can use BOSSA outside of Arduino. Where do you get it? Generic BOSSA installation files are available here: https://github.com/shumatech/BOSSA (formerly at http://sourceforge.net/projects/b-o-s-s-a/?source=dlp) Pre-built binaries are available: https://github.com/shumatech/BOSSA/releases The original Arduino DUE used a patched version of BOSSA available as source code here: https://github.com/shumatech/BOSSA/tree/arduino But that has most likely been incorporated into the main github repository. But, fortunately, since you already installed Arduino, you already have BOSSA installed. In my installation, it is here: .. code:: console C:\Program Files (x86)\Arduino\arduino-1.5.2\hardware\tools\bossac.exe On Debian like distribution, BOSSA can be install through repository: .. code:: console sudo apt install bossa-cli **General Procedure** 1. Erase the FLASH and put the Due in bootloader mode 2. Write the file to FLASH 3. Configure to boot from FLASH 4. Reset the DUE Erase FLASH and Put the Due in Bootloader Mode This is accomplished by simply configuring the programming port in 1200 baud and sending something on the programming port. Here is some sample output from a Windows CMD.exe shell. NOTE that my Arduino programming port shows up as COM26. It may be different on your system. To enter boot mode, set the baud to 1200 and send anything to the programming port: .. code:: console $ C:\Program Files (x86)\Arduino\arduino-1.5.2\hardware\tools>mode com26:1200,n,8,1 Status for device COM26: Baud: 1200 Parity: None Data Bits: 8 Stop Bits: 1 Timeout: ON XON/XOFF: OFF CTS handshaking: OFF DSR handshaking: OFF DSR sensitivity: OFF DTR circuit: ON RTS circuit: ON $ C:\Program Files (x86)\Arduino\arduino-1.5.2\hardware\tools>bossac.exe --port=COM26 --usb-port=false -i Device : ATSAM3X8 Chip ID : 285e0a60 Version : v1.1 Dec 15 2010 19:25:04 Address : 524288 Pages : 2048 Page Size : 256 bytes Total Size : 512KB Planes : 2 Lock Regions : 32 Locked : none Security : false Boot Flash : false Writing FLASH and Setting FLASH Boot Mode ----------------------------------------- In a Cygwin BaSH shell: .. code:: console $ export PATH="/cygdrive/c/Program Files (x86)/Arduino/arduino-1.5.2/hardware/tools":$PATH Erasing, writing, and verifying FLASH with bossac: $ bossac.exe --port=COM26 --usb-port=false -e -w -v -b nuttx.bin -R Erase flash Write 86588 bytes to flash [==============================] 100% (339/339 pages) Verify 86588 bytes of flash [==============================] 100% (339/339 pages) Verify successful Set boot flash true CPU reset. Some things that can go wrong: .. code:: console $ bossac.exe --port=COM26 --usb-port=false -e -w -v -b nuttx.bin -R No device found on COM26 This error means that there is code running on the Due already so the bootloader cannot connect. Press reset and try again: .. code:: console $ bossac.exe --port=COM26 --usb-port=false -e -w -v -b nuttx.bin -R No device found on COM26 Still no connection because Duo does not jump to bootloader after reset. Press ERASE button and try again: .. code:: console $ bossac.exe --port=COM26 --usb-port=false -e -w -v -b nuttx.bin -R Erase flash Write 86588 bytes to flash [==============================] 100% (339/339 pages) Verify 86588 bytes of flash [==============================] 100% (339/339 pages) Verify successful Set boot flash true CPU reset. In Linux shell: .. code:: console $ bossac -i --port=ttyACM0 -U false -e -w -v -b nuttx.bin -R Other useful ``bossac`` operations: a. Write code to FLASH don't change boot mode and don't reset. This lets you examine the FLASH contents that you just loaded while the bootloader is still active. .. code:: console $ bossac.exe --port=COM26 --usb-port=false -e -w -v --boot=0 nuttx.bin Write 64628 bytes to flash [==============================] 100% (253/253 pages) Verify 64628 bytes of flash [==============================] 100% (253/253 pages) Verify successful b. Verify the FLASH contents (the bootloader must be running) .. code:: console $ bossac.exe --port=COM26 --usb-port=false -v nuttx.bin Verify 64628 bytes of flash [==============================] 100% (253/253 pages) Verify successful c. Read from FLASH to a file (the bootloader must be running): .. code:: console $ bossac.exe --port=COM26 --usb-port=false --read=4096 nuttx.dump Read 4096 bytes from flash [==============================] 100% (16/16 pages) d. Change to boot from FLASH .. code:: console $ bossac.exe --port=COM26 --usb-port=false --boot=1 Set boot flash true Uploading NuttX to the Due Using JTAG ------------------------------------- The JTAG/SWD signals are brought out to a 10-pin header JTAG connector: .. csv-table:: :header: PIN,SIGNAL,JTAG STANDARD,NOTES 1 ,3.3V ,VTref, 2 ,JTAG_TMS ,SWDIO/TMS, "SAM3X pin 31, Pulled up on board" 3 ,GND ,GND, 4 ,JTAG_TCK ,SWDCLK/TCK, "SAM3X pin 28, Pulled up on board" 5 ,GND ,GND, 6 ,JTAG_TDO ,SWO/EXta/TRACECTL,"SAM3X pin 30, ulled up on board" 7 ,N/C ,Key, 8 ,JTAG_TDI ,NC/EXTb/TDI, "SAM3X pin 29, Pulled up on board" 9 ,GND ,GNDDetect, 10,MASTER-RESET ,nReset, You should be able to use a 10 to 20-pin adapter to connect a SAM-ICE debugger to the Arduino Due. I have this Olimex adapter: https://www.olimex.com/Products/ARM/JTAG/ARM-JTAG-20-10/. But so far I have been unable to get the get the SAM-ICE to communicate with the Due. Arduino DUE-specific Configuration Options ========================================== * ``CONFIG_ARCH``: Identifies the ``arch/`` subdirectory. This should be set to: * ``CONFIG_ARCH=arm`` * ``CONFIG_ARCH_family``: For use in C code: * ``CONFIG_ARCH_ARM=y`` * ``CONFIG_ARCH_architecture``: For use in C code: * ``CONFIG_ARCH_CORTEXM3=y`` * ``CONFIG_ARCH_CHIP``: Identifies the ``arch/*/chip`` subdirectory * ``CONFIG_ARCH_CHIP="sam34"`` * ``CONFIG_ARCH_CHIP_name``: For use in C code to identify the exact chip: * ``CONFIG_ARCH_CHIP_SAM34`` * ``CONFIG_ARCH_CHIP_SAM3X`` * ``CONFIG_ARCH_CHIP_ATSAM3X8E`` * ``CONFIG_ARCH_BOARD``: Identifies the ``boards/`` subdirectory and hence, the board that supports the particular chip or SoC. * ``CONFIG_ARCH_BOARD=arduino-due (for the Arduino Due development board)`` * ``CONFIG_ARCH_BOARD_name``: For use in C code * ``CONFIG_ARCH_BOARD_ARDUINO_DUE=y`` * ``CONFIG_ARCH_LOOPSPERMSEC``: Must be calibrated for correct operation of delay loops * ``CONFIG_RAM_SIZE``: Describes the installed DRAM (SRAM in this case): * ``CONFIG_RAM_SIZE=65536 (64Kb)`` * ``CONFIG_RAM_START``: The start address of installed DRAM * ``CONFIG_RAM_START=0x20000000`` * ``CONFIG_ARCH_LEDS``: Use LEDs to show state. Unique to boards that have LEDs Individual subsystems can be enabled: * ``CONFIG_SAM34_ADC12B``: 12-bit Analog To Digital Converter * ``CONFIG_SAM34_CAN0``: CAN Controller 0 * ``CONFIG_SAM34_CAN1``: CAN Controller 1 * ``CONFIG_SAM34_DACC``: Digital To Analog Converter * ``CONFIG_SAM34_DMAC0``: DMA Controller * ``CONFIG_SAM34_EMAC``: Ethernet MAC * ``CONFIG_SAM34_HSMCI``: High Speed Multimedia Card Interface * ``CONFIG_SAM34_PWM``: Pulse Width Modulation * ``CONFIG_SAM34_RTC``: Real Time Clock * ``CONFIG_SAM34_RTT``: Real Time Timer * ``CONFIG_SAM34_SDRAMC``: SDRAM Controller * ``CONFIG_SAM34_SMC``: Static Memory Controller * ``CONFIG_SAM34_SPI0``: Serial Peripheral Interface 0 * ``CONFIG_SAM34_SPI1``: Serial Peripheral Interface 1 * ``CONFIG_SAM34_SSC``: Synchronous Serial Controller * ``CONFIG_SAM34_TC0``: Timer Counter 0 * ``CONFIG_SAM34_TC1``: Timer Counter 1 * ``CONFIG_SAM34_TC2``: Timer Counter 2 * ``CONFIG_SAM34_TC3``: Timer Counter 3 * ``CONFIG_SAM34_TC4``: Timer Counter 4 * ``CONFIG_SAM34_TC5``: Timer Counter 5 * ``CONFIG_SAM34_TC6``: Timer Counter 6 * ``CONFIG_SAM34_TC7``: Timer Counter 7 * ``CONFIG_SAM34_TC8``: Timer Counter 8 * ``CONFIG_SAM34_TRNG``: True Random Number Generator * ``CONFIG_SAM34_TWIM``/``S0``: Two-Wire Interface 0 (master/slave) * ``CONFIG_SAM34_TWIM``/``S1``: Two-Wire Interface 1 (master/slave) * ``CONFIG_SAM34_UART0``: UART 0 * ``CONFIG_SAM34_UOTGHS``: USB OTG High Speed * ``CONFIG_SAM34_USART0``: USART 0 * ``CONFIG_SAM34_USART1``: USART 1 * ``CONFIG_SAM34_USART2``: USART 2 * ``CONFIG_SAM34_USART3``: USART 3 * ``CONFIG_SAM34_WDT``: Watchdog Timer Some subsystems can be configured to operate in different ways. The drivers need to know how to configure the subsystem. * ``CONFIG_SAM34_GPIOA_IRQ`` * ``CONFIG_SAM34_GPIOB_IRQ`` * ``CONFIG_SAM34_GPIOC_IRQ`` * ``CONFIG_SAM34_GPIOD_IRQ`` * ``CONFIG_SAM34_GPIOE_IRQ`` * ``CONFIG_SAM34_GPIOF_IRQ`` Configurations ============== Each Arduino Due configuration is maintained in a sub-directory and can be selected as follow: .. code:: console $ tools/configure.sh [OPTIONS] arduino-due: Where typical options are ``-l`` to configure to build on Linux or ``-c`` to configure for Cygwin under Linux. ``tools/configure.sh -h`` will show you all of the options. Before building, make sure the ``PATH`` environment variable includes the correct path to the directory than holds your toolchain binaries. And then build NuttX by simply typing the following. At the conclusion of the make, the nuttx binary will reside in an ELF file called, simply, ``nuttx``. .. code:: console $ make The ```` that is provided above as an argument to the ``tools/configure.sh`` must be one of the following. 1. These configurations use the mconf-based configuration tool. To change any of these configurations using that tool, you should: a. Build and install the kconfig-mconf tool. See nuttx/README.txt see additional README.txt files in the NuttX tools repository. b. Execute 'make menuconfig' in nuttx/ in order to start the reconfiguration process. 2. Unless stated otherwise, all configurations generate console output on UART0 which is available both on the USB virtual COM port and on the PWML connector (see the section "Serial Consoles" above). However, the pin usage by the ITEAD TFT shield conflict with the pin usage for UART0. In this case you need to switch to USART0 by modifying the configuration as follows: Board Selection -> Peripheral * ``CONFIG_SAM34_UART0=n``: Disable UART0. Can't use with this shield * ``CONFIG_SAM34_USART0=y``: Enable USART0 * ``CONFIG_USART0_SERIALDRIVER=y`` Device Drivers -> Serial * ``CONFIG_USART0_SERIAL_CONSOLE=y``: Configure the console on USART0 * ``CONFIG_USART0_RXBUFSIZE=256`` * ``CONFIG_USART0_TXBUFSIZE=256`` * ``CONFIG_USART0_BAUD=115200`` * ``CONFIG_USART0_BITS=8`` * ``CONFIG_USART0_PARITY=0`` * ``CONFIG_USART0_2STOP=0`` .. note:: USART0 TTL levels are available on COMM 5 (TXD0) and COMM 6 (RXD0). 3. Unless otherwise stated, the configurations are setup for Linux (or any other POSIX environment like Cygwin under Windows): Build Setup: * ``CONFIG_HOST_LINUX=y``: Linux or other POSIX environment 4. These configurations use the older, OABI, buildroot toolchain. But that is easily reconfigured: System Type -> Toolchain: * ``CONFIG_ARM_TOOLCHAIN_BUILDROOT=y``: Buildroot toolchain * ``CONFIG_ARM_TOOLCHAIN_BUILDROOT_OABI=y``: Older, OABI toolchain If you want to use the Atmel GCC toolchain, here are the steps to do so: Build Setup: * ``CONFIG_HOST_WINDOWS=y``: Windows * ``CONFIG_HOST_CYGWIN=y``: Using Cygwin or other POSIX environment System Type -> Toolchain: * ``CONFIG_ARM_TOOLCHAIN_GNU_EABI=y``: General GCC EABI toolchain under windows This re-configuration should be done before making NuttX or else the subsequent ``make`` will fail. If you have already attempted building NuttX then you will have to: 1. ``make distclean`` to remove the old configuration 2. ``tools/configure.sh sam3u-ek/ksnh`` to start with a fresh configuration 3. Perform the configuration changes above. Also, make sure that your ``PATH`` variable has the new path to your Atmel tools. Try ``which arm-none-eabi-gcc`` to make sure that you are selecting the right tool. nsh --- This configuration directory will build the NuttShell. 1. NSH built-in applications are supported. However, there are no built-in applications built with the default configuration. Binary Formats: * ``CONFIG_BUILTIN=y``: Enable support for built-in programs Application Configuration: * ``CONFIG_NSH_BUILTIN_APPS=y``: Enable starting apps from NSH command line 2. By default, this configuration uses UART0 and has support LEDs enabled. UART0 output is available on the USB debugging port or on pins 0-1 of the PWML connector. This configuration can be modified to use peripherals on the ITEAD TFT shield as described below. However, in that case the UART0 and LED "L" GPIO pins conflict with the pin usage by the ITEAD TFT Shield. In this case you need to switch to USART0 and disable LEDs by modifying the configuration as follows: Board Selection -> Peripheral * ``CONFIG_SAM34_UART0=n``: Disable UART0. Can't use with this shield * ``CONFIG_SAM34_USART0=y``: Enable USART0 * ``CONFIG_USART0_SERIALDRIVER=y`` Device Drivers -> Serial * ``CONFIG_USART0_SERIAL_CONSOLE=y``: Configure the console on USART0 * ``CONFIG_USART0_RXBUFSIZE=256`` * ``CONFIG_USART0_TXBUFSIZE=256`` * ``CONFIG_USART0_BAUD=115200`` * ``CONFIG_USART0_BITS=8`` * ``CONFIG_USART0_PARITY=0`` * ``CONFIG_USART0_2STOP=0`` .. note:: USART0 TTL levels are available on COMM 5 (TXD0) and COMM 6 (RXD0) Board Selection -> Board-Specific Options: * ``CONFIG_ARCH_LEDS=n``: Can't support LEDs with this shield installed * ``CONFIG_ARDUINO_ITHEAD_TFT=y``: Enable support for the Shield 3. If the ITEAD TFT shield is connected to the Arduino Due, then support for the SD card slot can be enabled by making the following changes to the configuration: .. note:: You cannot use UART0 or LEDs with this ITEAD module. You must switch to USART0 and disable LED support as described above. Board Selection -> Board-Specific Options: * ``CONFIG_ARDUINO_ITHEAD_TFT=y``: Enable support for the Shield File Systems: * ``CONFIG_DISABLE_MOUNTPOINT=n``: Mountpoint support is needed * ``CONFIG_FS_FAT=y``: Enable the FAT file system * ``CONFIG_FAT_LCNAMES=y``: Enable upper/lower case 8.3 file names (Optional, see below) * ``CONFIG_FAT_LFN=y``: Enable long file named (Optional, see below) * ``CONFIG_FAT_MAXFNAME=32``: Maximum supported file name length There are issues related to patents that Microsoft holds on FAT long file name technologies. See the top level NOTICE file for further details. Device Drivers * ``CONFIG_SPI=y``: Enable SPI support * ``CONFIG_SPI_EXCHANGE=y``: The exchange() method is supported * ``CONFIG_SPI_BITBANG=y``: Enable SPI bit-bang support * ``CONFIG_MMCSD=y``: Enable MMC/SD support * ``CONFIG_MMCSD_NSLOTS=1``: Only one MMC/SD card slot * ``CONFIG_MMCSD_MULTIBLOCK_LIMIT=0``: Should not need to disable multi-block transfers * ``CONFIG_MMCSD_HAVE_CARDDETECT=y``: I/O1 module as a card detect GPIO * ``CONFIG_MMCSD_SPI=y``: Use the SPI interface to the MMC/SD card * ``CONFIG_MMCSD_SPICLOCK=20000000``: This is a guess for the optimal MMC/SD frequency * ``CONFIG_MMCSD_SPIMODE=0``: Mode 0 is required Board Selection -> Common Board Options * ``CONFIG_NSH_ARCHINIT=y``: Initialize the MMC/SD slot when NSH starts * ``CONFIG_NSH_MMCSDSLOTNO=0``: Only one MMC/SD slot, slot 0 * ``CONFIG_NSH_MMCSDSPIPORTNO=0``: (does not really matter in this case) Application Configuration -> NSH Library * ``CONFIG_NSH_ARCHINIT=y``: Board has architecture-specific initialization .. warning:: 2013-7-2: SD card is not responding. All 0's received on SPI. 3. This configuration has been used for verifying the touchscreen on on the ITEAD TFT Shield. With the modifications below, you can include the touchscreen test program at apps/examples/touchscreen as an NSH built-in application. You can enable the touchscreen and test by modifying the default configuration in the following ways: .. note:: You cannot use UART0 or LEDs with this ITEAD module. You must switch to USART0 and disable LED support as described above. Board Selection -> Board-Specific Options: * ``CONFIG_ARDUINO_ITHEAD_TFT=y``: Enable support for the Shield Device Drivers * ``CONFIG_SPI=y``: Enable SPI support * ``CONFIG_SPI_EXCHANGE=y``: The exchange() method is supported * ``CONFIG_SPI_BITBANG=y``: Enable SPI bit-bang support * ``CONFIG_INPUT=y``: Enable support for input devices * ``CONFIG_INPUT_ADS7843E=y``: Enable support for the XPT2046 * ``CONFIG_ADS7843E_SPIDEV=0``: (Doesn't matter) * ``CONFIG_ADS7843E_SPIMODE=0``: Use SPI mode 0 * ``CONFIG_ADS7843E_FREQUENCY=1000000``: SPI BAUD 1MHz * ``CONFIG_ADS7843E_SWAPXY=y``: If landscape orientation * ``CONFIG_ADS7843E_THRESHX=51``: These will probably need to be tuned * ``CONFIG_ADS7843E_THRESHY=39`` System Type: * ``CONFIG_SAM34_GPIO_IRQ=y``: GPIO interrupt support * ``CONFIG_SAM34_GPIOC_IRQ=y``: Enable GPIO interrupts from port C Library Support: * ``CONFIG_SCHED_WORKQUEUE=y``: Work queue support required Application Configuration: * ``CONFIG_EXAMPLES_TOUCHSCREEN=y``: Enable the touchscreen built-int test Defaults should be okay for related touchscreen settings. Touchscreen debug output on USART0 can be enabled with: Build Setup: * ``CONFIG_DEBUG_FEATURES=y``: Enable debug features * ``CONFIG_DEBUG_INFO=y``: Enable verbose debug output * ``CONFIG_DEBUG_INPUT=y``: Enable debug output from input devices .. warning:: 2013-7-2: TSC is not responding. All 0's received on SPI. nsh-leds -------- This configuration directory will build the NuttX Shell and enable the user LEDS (``/dev/userleds``). It will also enable the LED example program (``leds``). Running the leds command will start up an LED daemon which will light up the L (user), TX, and RX LEDs in a binary sequence.