This is a fork from arduino/ArduinoCore-samd on GitHub. This will be used to maintain Arduino support for SAM M0+ boards including the MattairTech MT-D21E and the MT-D11 (see https://www.mattairtech.com/). It primarily adds support for new devices as well as a more flexible pin configuration / mapping system. It also adds some size optimizations (~7.5KB for blink sketch with CDC+HID+UART, ~2.5KB without USB or UART).

This core is intended to be installed using Boards Manager (see below). To update from a previous version, click on MattairTech SAM M0+ Boards in Boards Manager, then click Update.

• 1.6.6-mt3:

  • Fixes compilation with CDC_UART and CDC_ONLY settings

• 1.6.6-mt2:

  • Changes the default Communication setting to CDC_UART (from CDC_HID_UART)

• 1.6.6-mt1:

  • New documentation section 'Special Notes'. Please read!
  • Updated ASCII pinouts to be more readable and less ambiguous.
  • Updated the Signed driver for Windows (extras directory) (see CHANGELOG for details)
  • Merged in changes from upstream (see CHANGELOG for details)
  • Fix warnings about deprecated recipe.ar.pattern
  • Merged in changes from upstream SAMD CORE 1.6.2 2015.11.03 (see CHANGELOG for details)

• 1.6.7-beta-b0:
  • OS X support added (bossac for OS X can now upload to all supported chips) (Thanks @joseangeljimenez for testing)
  • New bossac upload tool (added support for SAML and SAMC)
  • New bootloader from upstream SAMD CORE (see bootloaders/zero/README.md)
  • New beta release method (see README.md)
  • Changing some names from 'SAMD' to 'SAM M0+'. The core will add L21 and C21 support soon.
  • Merged in changes from upstream SAMD CORE 1.6.3 2016.02.15 (see CHANGELOG for details)
  • Merged in changes from upstream SAMD CORE 1.6.4 2016.02.19 (see CHANGELOG for details)
  • Merged in changes from upstream SAMD CORE 1.6.5 2016.04.02 (see CHANGELOG for details)
  • Merged in changes from upstream SAMD 1.6.6 2016.05.19 (see CHANGELOG for details)

• Boards Manager must be opened twice to see some updates

• Errors when compiling, uploading, or burning the bootloader

  • Be sure to install the Arduino samd core before installing the MattairTech sam m0+ core. If you have problems upgrading the IDE to 1.6.6, you may need to uninstall both the Arduino and MattairTech cores, then re-install in the proper order. Use Arduino core 1.6.2 or above.

• Tools->Communications menu

  • Currently, the Tools->Communications menu must be used to select the communications configuration. This configuration must match the included libraries. For example, when including the HID and Keyboard libraries, you must select an option that includes HID (ie: CDC_HID_UART). This menu is currently needed to select the USB PID that matches the USB device configuration (needed for Windows). This may become automatic in a future release.

    • Be sure that the Tools->Communications menu matches the sketch and libraries you are compiling.
    • Different combinations of USB devices will result in different COM port assingments in Windows.

• Incude platform specific libraries

  • You may need to manually include platform specific libraries such as SPI.h, Wire.h, and HID.h.

• Differences from Arduino in versioning

  • The MattairTech ArduinoCore-samd version currently tracks the IDE version. In some cases, it may indicate the minimum IDE version. This is the case for both 1.6.5-mtX and 1.6.6-mtX (which corresponds to SAMD CORE 1.6.2). 1.6.6-mt1 corresponds to Arduino SAMD CORE 1.6.2 plus some pull requests.

• TODO

Most pins have multiple configurations available (even analog pins). For example, pin A10 on the MT-D21E can be an analog input, a PWM output, Digital I/O, or the TX pin of 'Serial1'. These always reference the pin number printed on the board but without the 'A' (with the usable pins starting at 2). DO NOT connect voltages higher than 3.3V!

============================= MattairTech MT-D21E (ATsamd21eXXa) ========================
Other  INT     PWM   Digital  Analog                     Digital  PWM      INT      Other
=========================================================================================
                                      -------------------
Xin32                                | A0            RST |                          Reset
Xout32                               | A1            NC  |
DAC                     2   2(ADC0)  | A2            NC  |
REF                     3   3(ADC1)  | A3            A31 | 31  31(TCC11) 31(INT11) SWDIO*
     4(INT4)            4   4(ADC4)  | A4            A30 | 30  30(TCC10) 30(INT10) SWDCLK
     5(INT5)            5   5(ADC5)  | A5            NC  |
                        6   6(ADC6)  | A6            A28 | 28            28(INT8)   LED
VDIV                    7   7(ADC7)  | A7            A27 | 27            27(INT15)  BTNA
    8(INTNMI) 8(TCC00)  8   8(ADC16) | A8            A23 | 23  23(TC41)  23(INT7)   SS
    9(INT9)   9(TCC01)  9   9(ADC17) | A9            A22 | 22  22(TC40)  22(INT6)   MISO
TX1          10(TCC02)  10  10(ADC18)| A10           A19 | 19            19(INT3)   SCK
RX1          11(TCC03)  11  11(ADC19)| A11           A18 | 18            18(INT2)   MOSI
TX2 14(INT14) 14(TC30)  14           | A14           A17 | 17  17(TCC21)  17(INT1)  SCL
RX2           15(TC31)  15           | A15           A16 | 16  16(TCC20)  16(INT0)  SDA
                                     | NC            NC  |
                                     | NC            NC  |
                                     | Vbus          3.3V|   * Button B available on 31
USB D-                               | A24-  _____   Vcc |
USB D+                               | A25+ |     |  Vin |
                                     | Gnd  | USB |  Gnd |
                                      -------------------

=========================== MattairTech MT-D11 (ATsamd11D14AM) ==========================
Other  INT   PWM   Digital  Analog                    Digital   PWM      INT     Other
=========================================================================================
                                    -------------------
DAC                   2   2(ADC0)  | A2   | USB |  Gnd |
REF                   3   3(ADC1)  | A3   |     |  Vcc |
   4(INT4)  4(TCC00)  4   4(ADC2)  | A4    -----   A31 | 31  31(TC21)  31(INT3)  RX/SWDIO
   5(INT5)  5(TCC01)  5   5(ADC3)  | A5            A30 | 30  30(TC20)           TX/SWDCLK
            6(TCC02)  6   6(ADC4)  | A6            A27 | 27            27(INT7)
            7(TCC03)  7   7(ADC5)  | A7            A23 | 23                      SCL
MOSI  10(INT2)        10  10(ADC8) | A10           A22 | 22            22(INT6)  SDA
SCK                   11  11(ADC9) | A11           A17 | 17  17(TC11)
MISO  14(INTNMI)      14  14(ADC6) | A14           A16 | 16  16(TC10)  16(INT0)  LED
BTN/SS  15(INT1)      15  15(ADC7) | A15           RST |                         Reset
                                    -------------------

• Digital: All pins can be used for general purpose I/O
  • Supports INPUT, OUTPUT, INPUT_PULLUP, and INPUT_PULLDOWN.
  • Each pin can source or sink a maximum of 7 mA (when PER_ATTR_DRIVE_STRONG is set for the pin).
  • Internal pull-up and pull-down resistors of 20-60 Kohms (40Kohm typ., disconnected by default).
  • Use the pinMode(), digitalWrite(), and digitalRead() functions.
• Analog Inputs: 10 pins can be configured as ADC analog inputs.
  • These are available using the analogRead() function.
  • All pins can be used for GPIO and some pins can be used for other digital functions (ie. pwm or serial).
  • Each pin provides 10 bits of resolution (1024 values) by default.
  • 12-bit resolution supported by using the analogReadResolution() function.
  • Each pin measures from ground to 3.3 volts.
  • The upper end of the measurement range can be changed using the AREF pin and the analogReference() function.
• DAC: One analog output is available on pin 2.
  • Provides a 10-bit voltage output with the analogWrite() function.
• PWM: 12 pins (MT-D21E) or 8 pins (MT-D11) can be configured as PWM outputs.
  • Available using the analogWrite() function.
  • Each pin provides 8 bits of resolution (256 values) by default.
  • 12-bit resolution supported by using the analogWriteResolution() function.
• External Interrupts: 15 pins (MT-D21E) or 9 pins (MT-D11) can be configured with external interrupts.
  • Available using the attachInterrupt() function.
• Serial: 2 pairs of pins (MT-D21E) or 1 pair (MT-D11) can be configured for TTL serial I/O.
  • MT-D21E: Serial1: pin 11 (RX) and pin 10 (TX). Serial2: pin 15 (RX) and pin 14 (TX).
  • MT-D11: Serial1: pin 31 (RX) and pin 30 (TX).
• SPI: 3 or 4 pins can be configured for SPI I/O (SPI).
  • MT-D21E: Pin 18 (MOSI), pin 19 (SCK), pin 22 (MISO), and optionally pin 23 (SS, not currently used).
  • MT-D11: Pin 10 (MOSI), pin 11 (SCK), pin 14 (MISO), and optionally pin 15 (SS, not currently used).
  • SPI communication using the SPI library.
  • Note that the SPI library will set SS as an output.
  • On the MT-D11, the button must be configured as reset (default) when using SPI.
• TWI (I2C): 2 pins can be configured for TWI I/O (Wire).
  • MT-D21E: Pin 16 (SDA) and pin 17 (SCL).
  • MT-D11: Pin 22 (SDA) and pin 23 (SCL).
  • TWI communication using the Wire library.
• LED: One pin can be configured to light the onboard LED (LED_BUILTIN).
  • Pin 28 (MT-D21E) or pin 16 (MT-D11). Bring the pin HIGH to turn the LED on. The pullup is disabled on this pin.
• Button: One pin can be configured to read the onboard Button A (BUTTON_BUILTIN).
  • Pin 27 (MT-D21E) or pin 15 (MT-D11). Pressing the button will bring the pin LOW. The pullup must be enabled first.
  • If the debouncing capacitor is connected, delay reading the pin at least 6ms after turning on the pullup.
• AREF: One pin can be configured as an AREF analog input.
  • The upper end of the analog measurement range can be changed using the analogReference() function.
• Reset: Bring this line LOW to reset the microcontroller.

• The 32.768KHz crystal is used by the Arduino core, so it MUST be connected via the solder jumpers.
• The sketch in some cases can run without the crystal attached, but the clock will be very inaccurate.
• The 16MHz crystal is not used. It should be disconnected via the solder jumpers.
• The I2C (TWI) pullup resistors should be enabled via the solder jumpers.
• The LED should be enabled via the solder jumper.
• Button A and the debouncing capacitor should be connected via the solder jumpers.
• Button B (MT-D21E only) is connected to the Reset pin by default, but can be connected to pin 31 via the solder jumper.
• A reference voltage can be connected to AREF. In this case, the capacitors should be enabled via the solder jumpers.
• On the MT-D11, BTN is shared with SPI SS, so the button must be configured as reset (default) when using SPI.

To print to the Serial Monitor over USB, use 'Serial'. Serial points to SerialUSB (Serial1 and Serial2 are UARTs). Unlike most Arduino boards (ie. Uno), SAM M0+ boards do not automatically reset when the serial monitor is opened. To see what your sketch outputs to the serial monitor from the beginning, the sketch must wait for the SerialUSB port to open first. Add the following to setup():

while (!Serial) ;

Remember that if the sketch needs to run without SerialUSB connected, another approach must be used. You can also reset the board manually with the Reset button if you wish to restart your sketch. However, pressing the Reset button will reset the SAM M0+ chip, which in turn will reset USB communication. This interruption means that if the serial monitor is open, it will be necessary to close and re-open it to restart communication.

• 180 bytes of flash can be saved on the MT-D11 by using PIN_MAP_COMPACT (see 'New PinDescription Table' below).
• Datalogger compiled without USB or UART support, but with SPI and SD (with FAT filesystem) support. Serial output was disabled.
• Note that USB CDC is required for auto-reset into the bootloader to work (otherwise, manually press reset twice in quick succession).
• USB uses primarily 3 buffers totaling 1024 bytes. The UART uses a 96 byte buffer. The banzai() function (used for auto-reset) resides in RAM and uses 72 bytes.
• Any combination of CDC, HID, or UART can be used (or no combination), by using the Tools->Communication menu.

The flash used message at the end of compilation is not correct. The number shown represents the .text segment only. However, Flash usage = .text + .data segments (RAM usage = .data + .bss segments). In this release, two programs are run at the end of compilation to provide more detailed memory usage. To enable this output, go to File->Preferences and beside "Show verbose output during:", check "compilation".

Just above the normal flash usage message, is the output from the size utility. However, this output is also incorrect, as it shows .text+.data in the .text field, but 0 in the .data field. However, the .text field does show the total flash used. The .data field can be determined by subtracting the value from the normal flash usage message (.text) from the value in the .text field (.text+.data). The .bss field is correct.

Above the size utility output is the output from the nm utility. The values on the left are in bytes. The letters stand for: T(t)=.text, D(d)=.data, B(b)=.bss, and everything else (ie: W) resides in flash (in most cases).

Prior to core version 1.6.6-mt1, sketches compiled with both CDC and HID USB code by default, thus requiring a CDC driver for the bootloader and a CDC-HID driver for sketches. Now that PluggableUSB is supported, sketches compile with only CDC code by default. Thus, only one driver is needed. Since HID and MIDI are currently supported (and MSD potentially in the future), driver installation will be required for each different combination of USB devices. There are currently four USB composite device combinations that include CDC as well as a CDC only device. Each supported combination has a unique USB VID:PID pair, and these are listed in the .inf file. Once the first device is installed (the CDC only device), future installations might be automatic, otherwise, you may direct the installer to the same .inf file. The drivers are signed and support both 32 and 64 bit versions of Windows XP(SP3), Vista, 7, 8, and 10.

1. If you do not already have the SAM-BA bootloader installed, see below.
2. Download https://www.mattairtech.com/software/MattairTech_CDC_Driver_Signed.zip and unzip into any folder.
3. Plug in the board while holding down button A to enter the bootloader. The LED should light.
4. Windows will detect the board. Point the installer to the folder from above to install the bootloader driver.
5. If you don't intend on using Arduino, you can skip the rest of this list. See Using Bossac Standalone below.
6. If you do not already have the test firmware installed (comes preinstalled), see Using Bossac Standalone below.
7. Press the reset button to run the test firmware (blink sketch).
8. Windows will detect the board. Point the installer to the above folder to install the sketch driver (if needed).
9. Continue with SAM M0+ Core Installation below.

0. No driver installation is needed.
1. On some distros, you may need to add your user to the same group as the port (ie: dialout) and/or set udev rules.
2. You MAY have to install and use Arduino as the root user in order to get reliable access to the serial port.
   • This is true even when group permissions are set correctly, and it may fail after previously working.
   • You can also create/modify a udev rule to set permissions on the port so everyone can read / write.
3. Continue with SAM M0+ Core Installation below.

OS X support currently in beta (see below), the following instructions are still for 1.6.6-mtX.

1. Only the 256 KB chip variants work with the OS X version of the upload tool, bossac.
2. First, you will need to open boards.txt and change mattairtech_mt_d21e_bl8k.upload.tool to equal arduino:bossac.
3. Open platform.txt and change tools.bossac.path to equal{runtime.tools.bossac-1.6.1-arduino.path}.
4. No driver installation is needed.
5. Plug in the board. You may get a dialog box asking if you wish to open the “Network Preferences”:
   • Click the "Network Preferences..." button, then click "Apply".
   • The board will show up as “Not Configured”, but it will work fine.
6. Continue with SAM M0+ Core Installation below.

• To update from a previous version, click on MattairTech SAM M0+ Boards in Boards Manager, then click Update.
• Boards Manager may require opening twice (with possibly a delay in between) to see some updates.

1. The MattairTech SAM M0+ Core requires Arduino 1.6.7 (1.6.5-mtX required IDE 1.6.5).
2. In the Arduino IDE, click File->Preferences.
3. Click the button next to Additional Boards Manager URLs.
4. Add https://www.mattairtech.com/software/arduino/package_MattairTech_index.json.
5. Save preferences, then open the Boards Manager.
6. Install the Arduino SAM M0+ Boards package. Use version 1.6.2 or higher.
7. Install the MattairTech SAM M0+ Boards package (1.6.7).
8. Close Boards Manager, then click Tools->Board->MattairTech MT-D21E (or MT-D11).
9. Select the processor with the now visible Tools->Processor menu.
10. If you do not already have the bootloader or blink sketch installed, see SAM-BA USB CDC Bootloader below.
11. Plug in the board. The blink sketch should be running.
12. Click Tools->Port and choose the COM port.
13. You can now upload your own sketch.

1. In the Arduino IDE 1.6.7 (or above), open File->Examples->01.Basics->Blink.
2. Change the three instances of '13' to 'LED_BUILTIN'.
3. Be sure the correct options are selected in the Tools menu (see AVR Core Installation above).
4. With the board plugged in, select the correct port from Tools->Port.
5. Click the Upload button. After compiling, the sketch should be transferred to the board.
6. Once the bootloader exits, the blink sketch should be running.

The SAM-BA bootloader has both a CDC USB interface, and a UART interface (TX: pin 10, RX: pin 11, 8N1). It is compatible with the Arduino IDE (Zero compatible), or it can be used with the Bossac tool standalone. Under Arduino, auto-reset is supported (automatically runs the bootloader while the sketch is running) as well as automatic return from reset. The SAM-BA bootloader described here adds to the Arduino version, which in turn is based on the bootloader from Atmel. The Arduino version added several features, including three new commands (Arduino Extended Capabilities) that increase upload speed. The bootloader normally requires 8 KB FLASH, however, a 4 KB version can be used for the D11 chips.

Bossac is a command line utility for uploading firmware to SAM-BA bootloaders. It runs on Windows. Linux, and OS X. It is used by Arduino to upload firmware to SAM and SAM M0+ boards. The version Bossac described here adds to the Arduino version (https://github.com/shumatech/BOSSA, Arduino branch), which in turn is a fork from the original Bossa (http://www.shumatech.com/web/products/bossa). It adds support for more SAM M0+ chips (D21, L21, C21, and D11).

Note that only the Arduino or Mattairtech versions of bossac are currently supported for SAM M0+ chips. Neither the stock bossac (or Bossa) nor the Atmel SAM-BA upload tool will work.

Arduino Extended Capabilities:

• X: Erase the flash memory starting from ADDR to the end of flash.
• Y: Write the content of a buffer in SRAM into flash memory.
• Z: Calculate the CRC for a given area of memory.

The bootloader can be started by:

• Tapping reset twice in quick succession (BOOT_DOUBLE_TAP).
• Holding down button A (BOOT_LOAD_PIN) while powering up.
• Clicking 'Upload Sketch' in the Arduino IDE, which will automatically start the bootloader (when CDC is enabled).
• If the application (sketch) area is blank, the bootloader will run.

Otherwise, it jumps to application and starts execution from there. The LED will light during bootloader execution. Note that the 4KB bootloader does not support the Arduino Extended Capabilities or BOOT_DOUBLE_TAP. However, BOOT_DOUBLE_TAP does fit into the SAMD11 4KB bootloader.

When the Arduino IDE initiates the bootloader, the following procedure is used:

1. The IDE opens and closes the USB serial port at a baud rate of 1200bps. This triggers a “soft erase” procedure.
2. The first row of application section flash memory is erased by the MCU. If it is interrupted for any reason, the erase procedure will likely fail.
3. The board is reset. The bootloader (which always runs first) detects the blank flah row, so bootloader operation resumes.
4. Opening and closing the port at a baud rate other than 1200bps will not erase or reset the SAM M0+.

1. If you do not already have the MattairTech SAM M0+ core installed, see SAM M0+ Core Installation above.
2. Plug in the SAM M0+ board. The bootloader must be running to (press reset twice within 500ms).
3. Plug an Atmel ICE into USB, then connect it to the powered SAM M0+ board. A green LED should light on the Atmel ICE.
4. Click Tools->Programmer->Atmel ICE.
5. Click Tools->Board->MattairTech MT-D21E (or MT-D11).
6. Click Tools->Processor and select your chip.
7. Click Tools->Burn Bootloader. Ignore any messages about not supporting shutdown or reset.
8. Continue with driver installation above.

A running sketch may interfere with the bootloader installation process. Be sure you are running the existing bootloader or using a blank chip.

1. Download the bootloader from https://www.mattairtech.com/software/arduino/SAM-BA-bootloaders-zero-mattairtech.zip.
2. Unzip to any directory. Be sure that a bootloader is available for your particular chip.
3. Follow the procedures for your upload tool to upload the firmware.
   • Perform a chip erase first. Be sure no BOOTPROT bits are set.
   • Install the binary file to 0x00000000 of the FLASH.
   • You can optionally set the BOOTPROT bits to 8KB (or 4KB for the MT-D11). The Arduino installation method does not set these.
   • You can optionally set the EEPROM bits or anything else. The Arduino installation method uses factory defaults.
4. Continue with driver installation above.

When using Bossac standalone, you will need to ensure that your application starts at 0x00002000 for 8 KB bootloaders, and 0x00001000 for 4 KB bootloaders. This is because the bootloader resides at 0x00000000. This can be accomplished by passing the following flag to the linker (typically LDFLAGS in your makefile; adjust for your bootloader size):

Wl,sectionstart=.text=0x2000

You may also use a linker script. See the MattairTech SAM M0+ package for examples. Be sure to generate and use a binary file. Many makefiles are set up to generate an elf, hex, and bin already.

Download Bossac from:

• https://www.mattairtech.com/software/arduino/bossac-1.6.1-arduino-mattairtech-1-mingw32.tar.bz2 (Windows 32 bit and 64 bit)
• https://www.mattairtech.com/software/arduino/bossac-1.6.1-arduino-mattairtech-1-x86_64-linux-gnu.tar.bz2 (Linux 64 bit)
• https://www.mattairtech.com/software/arduino/bossac-1.6.1-arduino-mattairtech-1-i686-linux-gnu.tar.bz2 (Linux 32 bit)
• https://www.mattairtech.com/software/arduino/bossac-1.6.1-arduino-mattairtech-1-x86_64-apple-darwin.tar.bz2 (OS X 64 bit)

Linux 64 bit users can also download Bossa (GUI) and bossash (shell) from:

• https://www.mattairtech.com/software/arduino/Bossa-1.6.1-arduino-mattairtech-1-x86_64-linux-gnu.tar.bz2 (Linux 64 bit)

As an example, bossac will be used to upload the test firmware (blink sketch):

1. Download firmware from https://www.mattairtech.com/software/SAM-BA-bootloader-test-firmware.zip and unzip.
2. If you have not already installed the bootloader driver, see Driver Installation above.
3. Be sure there is a binary that matches your chip. On the command line (change the binary to match yours):

bossac.exe -d --port=COM5 -U true -i -e -w -v Blink_Demo_ATSAMD21E18A.bin -R

4. On Linux --port might be /dev/ttyACM0. If the device is not found, remove the --port argument for auto-detection.
5. See http://manpages.ubuntu.com/manpages/vivid/man1/bossac.1.html for details.
6. The board should reset automatically and the sketch should be running.

/*   The PinDescription table describes how each of the pins can be used by the Arduino
 *   core. Each pin can have multiple functions (ie: ADC input, digital output, PWM,
 *   communications, etc.), and the PinDescription table configures which functions can
 *   be used for each pin. This table is mainly accessed by the pinPeripheral function in
 *   wiring_private.c, which is used to attach a pin to a particular peripheral function.
 *   The communications drivers (ie: SPI, I2C, and UART), analogRead(), analogWrite(),
 *   analogReference(), attachInterrupt(), and pinMode() all call pinPeripheral() to
 *   verify that the pin can perform the function requested, and to configure the pin for
 *   that function. Most of the contents of pinMode() are now in pinPeripheral().
 * 
 *   There are two ways that pins can be mapped. The first is to map pins contiguously
 *   (no PIO_NOT_A_PIN entries) in the table. This results in the least amount of space
 *   used by the table. A second method, used by default by the MT-D21E and MT-D11, maps
 *   Arduino pin numbers to the actual port pin number (ie: Arduino pin 28 = Port A28).
 *   This only works when there is one port. Because not all port pins are available,
 *   PIO_NOT_A_PIN entries must be added for these pins and more FLASH space is consumed.
 *   For an example of both types, see variant.cpp from the MT-D11 variant.
 * 
 *   Explanation of PinDescription table:
 * 
 *   Port                  This is the port (ie: PORTA).
 *   Pin                   This is the pin (bit) within the port. Valid values are 0-31.
 *   PinType               This indicates what peripheral function the pin can be
 *                         attached to. In most cases, this is PIO_MULTI, which means
 *                         that the pin can be anything listed in the PinAttribute field.
 *                         It can also be set to a specific peripheral. In this case, any
 *                         attempt to configure the pin (using pinPeripheral or pinMode)
 *                         as anything else will fail (and pinPeripheral will return -1).
 *                         This can be used to prevent accidental re-configuration of a
 *                         pin that is configured for only one function (ie: USB D- and
 *                         D+ pins). If a pin is not used or does not exist,
 *                         PIO_NOT_A_PIN must be entered in this field. See WVariant.h
 *                         for valid entries. These entries are also used as a parameter
 *                         to pinPeripheral() with the exception of PIO_NOT_A_PIN and
 *                         PIO_MULTI. The pinMode function now calls pinPeripheral() with
 *                         the desired mode. Note that this field is not used to select
 *                         between the two peripherals possible with each of the SERCOM
 *                         and TIMER functions. PeripheralAttribute is now used for this.
 *   PeripheralAttribute   This is an 8-bit bitfield used for various peripheral
 *                         configuration. It is primarily used to select between the two
 *                         peripherals possible with each of the SERCOM and TIMER
 *                         functions. TIMER pins are individual, while SERCOM uses a
 *                         group of two to four pins. This group of pins can span both
 *                         peripherals. For example, pin 19 (SPI1 SCK) on the MT-D21E
 *                         uses PER_ATTR_SERCOM_ALT while pin 22 (SPI1 MISO) uses
 *                         PER_ATTR_SERCOM_STD. Both TIMER and SERCOM can exist for each
 *                         pin. This bitfield is also used to set the pin drive strength.
 *                         In the future, other attributes (like input buffer
 *                         configuration) may be added. See WVariant.h for valid entries.
 *   PinAttribute          This is a 32-bit bitfield used to list all of the valid
 *                         peripheral functions that a pin can attach to. This includes
 *                         GPIO functions like PIN_ATTR_OUTPUT. Certain attributes are
 *                         shorthand for a combination of other attributes.
 *                         PIN_ATTR_DIGITAL includes all of the GPIO functions, while
 *                         PIN_ATTR_TIMER includes both PIN_ATTR_TIMER_PWM and
 *                         PIN_ATTR_TIMER_CAPTURE (capture is not used yet).
 *                         PIN_ATTR_ANALOG is an alias to PIN_ATTR_ANALOG_ADC. There is
 *                         only one DAC channel, so PIN_ATTR_DAC appears only once. This
 *                         bitfield is useful for limiting a pin to only input related
 *                         functions or output functions. This allows a pin to have a
 *                         more flexible configuration, while restricting the direction
 *                         (ie: to avoid contention). See WVariant.h for valid entries.
 *   TCChannel             This is the TC(C) channel (if any) assigned to the pin. Some
 *                         TC channels are available on multiple pins (ie: TCC0/WO[0] is
 *                         available on pin A4 or pin A8 on the MT-D21E). In general,
 *                         only one pin should be configured (in the pinDescription
 *                         table) per TC channel. See WVariant.h for valid entries.
 *                         The tone library uses TC5 (MT-D21E) or TC2 (MT-D11).
 *   ADCChannelNumber      This is the ADC channel (if any) assigned to the pin. See
 *                         WVariant.h for valid entries.
 *   ExtInt                This is the interrupt (if any) assigned to the pin. Some
 *                         interrupt numbers are available on multiple pins (ie:
 *                         EIC/EXTINT[2] is available on pin A2 or pin A18 on the
 *                         MT-D21E). In general, only one pin should be configured (in
 *                         the pinDescription table) per interrupt number. Thus, if an
 *                         interrupt was needed on pin 2, EXTERNAL_INT_2 can be moved
 *                         from pin 18. See WVariant.h for valid entries.
 */

• SAML21 and C21 support is currently under development

• Timer library is currently under development (like TimerOne, plus input capture, plus ??)

• OS X support currently in beta testing

• USB Host mode CDC ACM (partially complete; BSD-like license?)

• Features for lower power consumption (library?)

• Enhanced SD card library

• Optional use of single on-board LED as USB activity LED

• MSC (Mass Storage) USB Device Class

• Polyphonic tone

• Wired-AND, Wired-OR for port pins

• High-speed port pin access (IOBUS)

• Libraries for some hardware I plan on using:

  • TFT LCD (CFAF128128B-0145T)
  • Motor controller (LV8711T)
  • IR decoder
  • I2S DAC/AMP and I2S MEMS microphone
  • Battery management IC
  • XBee/Xbee Pro devices
  • RS485
  • Several I2C (Wire) sensor devices:
    • Accelerometer/magnetometer (LSM303CTR)
    • Barometer/altimeter (LPS22HBTR)
    • Humidity/temperature
    • Light/color sensor

The Changelog has moved to a separate file named CHANGELOG. The most recent changes are still in the 'What's New' section above.

If you find a bug you can submit an issue here on github:

https://github.com/mattairtech/ArduinoCore-samd/issues

Before posting a new issue, please check if the same problem has been already reported by someone else to avoid duplicates.

Contributions are always welcome. The preferred way to receive code cotribution is by submitting a Pull Request on github.

Periodically, a beta is released for testing.

The beta builds are available through Boards Manager. If you want to install them:

1. Open the Preferences of the Arduino IDE.
2. Add this URL https://www.mattairtech.com/software/arduino/beta/package_MattairTech_index.json in the Additional Boards Manager URLs field, and click OK.
3. Open the Boards Manager (menu Tools->Board->Board Manager...)
4. Install MattairTech SAM M0+ Boards - Beta build
5. Select one of the boards under MattairTech SAM M0+ Beta Build XX in Tools->Board menu
6. Compile/Upload as usual

The Arduino IDE will notify the user if an update to the beta is available, which can then be installed automatically. Alternatively, if a particular beta is needed, replace the url in step 2 with: https://www.mattairtech.com/software/arduino/beta/package_MattairTech_sam_m0p-${VERSION}-beta-b${BUILD_NUMBER}_index.json where ${VERSION} and ${BUILD_NUMBER} match the beta name as shown in the CHANGELOG (ie: package_MattairTech_sam_m0p-1.6.7-beta-b0_index.json). In this case, the IDE will not notify the user of updates.

This core has been developed by Arduino LLC in collaboration with Atmel. This fork developed by Justin Mattair of MattairTech LLC.

  Copyright (c) 2015 Arduino LLC.  All right reserved.

  This library is free software; you can redistribute it and/or
  modify it under the terms of the GNU Lesser General Public
  License as published by the Free Software Foundation; either
  version 2.1 of the License, or (at your option) any later version.

  This library is distributed in the hope that it will be useful,
  but WITHOUT ANY WARRANTY; without even the implied warranty of
  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
  See the GNU Lesser General Public License for more details.

  You should have received a copy of the GNU Lesser General Public
  License along with this library; if not, write to the Free Software
  Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301  USA