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An open source SDK for the Joyetech eVic VTC Mini.

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eVic SDK is a software development kit for writing APROMs for the Joyetech eVic VTC Mini.

Setting up the environment

To use evic-sdk, you need a working arm-none-eabi GCC toolchain, binutils and libc. On Linux, most distros have precompiled packages in their repos. For example, on Fedora, install the following packages:

arm-none-eabi-gcc
arm-none-eabi-newlib

On Ubuntu, the following should be enough:

gcc-arm-none-eabi
libnewlib-arm-none-eabi

On OSX you can use brew:

brew tap mpaw/arm-none-eabi
brew update
brew install gcc-arm-none-eabi

On Windows, first install the precompiled ARM toolchain. Choose an installation path without spaces to avoid problems with the build process. Then, install Cygwin and add the following packages on top of the base install:

make
git

On any OS, you also need a working python-evic install.

On Cygwin, hidapi (needed by python-evic) won't build as-is. There are various issues (Cygwin not recognized as a target, DLL naming conflict, HID open permissions). Follow those instructions to get python-evic to work on Cygwin:

  1. Install the following packages (python, basic build environment, libs and utils):

    binutils
    gcc-core
    gcc-g++
    python3
    python3-setuptools
    libhidapi0
    libhidapi-devel
    libusb1.0
    libusb1.0-devel
    wget
    patch
    
  2. Download, patch and install hidapi:

    wget https://pypi.python.org/packages/source/h/hidapi/hidapi-0.7.99.post12.tar.gz
    wget http://pastebin.com/raw/16E7UdNF && echo >> 16E7UdNF
    tar -zxvf hidapi-0.7.99.post12.tar.gz
    patch -s -p0 < 16E7UdNF
    cd hidapi-0.7.99.post12
    python3 setup.py install
    
  3. Download and install python-evic:

    git clone https://github.com/Ban3/python-evic
    cd python-evic
    python3 setup.py install
    

Installation

  1. Clone this repository:

    git clone https://github.com/ReservedField/evic-sdk.git
    cd evic-sdk
    
  2. Download the latest M451 series SDK from Nuvoton and copy the Library folder inside evic-sdk/nuvoton-sdk, as to have evic-sdk/nuvoton-sdk/Library.

  3. Point the EVICSDK environment variable to the evic-sdk folder. This should do (assuming your current directory is evic-sdk):

    echo "export EVICSDK=$(pwd)" >> $HOME/.bashrc
    

    Make sure to restart your terminal to ensure variables are set before building.

  4. Build the SDK:

    make
    

At this point, the SDK should be fully set up. You can also generate Doxygen documentation with:

make docs

To clean up the build (for example if you want to do a full rebuild), use the standard:

make clean

Building your first APROM

The helloworld example should be the first thing you try compiling and flashing, to check that everything is working correctly. Building is as easy as:

cd example/helloworld
make

To clean you can use make clean, as usual. If the build succeeds, you should now have a bin/helloworld.bin file ready to flash. This file is encrypted and compatible with the official updater. You can also generate a unencrypted binary:

make helloworld_unencrypted.bin

Flashing

You can flash the output binary using the official updater. For development, using python-evic is quicker and simpler. I suggest to backup your dataflash before flashing, in case anything goes south:

evic dump-dataflash -o data.bin

Now, flash:

evic upload bin/helloworld.bin

If everything went well you should see the "Hello, World." message.

This APROM doesn't include USB updating, so you need to reboot to LDROM to flash something else. To do it, remove the battery and disconnect the USB cable. Then, holding the right button, connect the USB cable. Now you can let the button go and flash away. You can also insert the battery while the button is pressed, then let it go and connect the cable. I find powering over USB is more convenient (as long as the APROM doesn't require significant power, i.e. it doesn't fire the atomizer). Similiarly, holding the left button during powerup will force the system to boot from APROM.

If python-evic fails and the eVic won't flash back to a functioning state, don't panic. Find a Windows/Mac machine (or virtualize one), boot the eVic to LDROM and flash an original firmware using the official Joyetech updater. It has always worked for me.

Unless you're messing with the LDROM, this is practically unbrickable - you can always boot to LDROM and restore. Actually, APROM update is always done from LDROM - the official firmware doesn't even contain flash writing routines, it only provides access to the dataflash and the actual APROM upload happens in LDROM after a reset.

USB debugging

The SDK provides a working CDC-compliant USB virtual COM port driver. This allows you to communicate with a computer for debugging purposes. On Linux and Mac it's plug-and-play. On Windows, you have to create an INF file with the virtual COM VID/PID pair to get it to install the driver. An example can be found in the Nuvoton SDK, under SampleCode/StdDriver/USBD_VCOM_SinglePort/Windows Driver.

An example on how to use the port is given in example/usbdebug. You can communicate with it using your favorite serial port terminal. All the line coding parameters (baud rate, parity, stop bits, data bits) are ignored, so you don't need to worry about them.

Coding guidelines

While the SDK does a fairly good job of abstracting the low-level details, you still need to remember that you're coding on an embedded platform. A few tips that might be useful:

  • You should declare all variables shared between your main code and callbacks/interrupt handlers as volatile.
  • Try to minimize dynamic memory allocation: all memory not used by data or stack is assigned to heap, but RAM is only 32kB.
  • Declare constant data (such as lookup tables) as const: the compiler will place it in the ROM, reducing RAM usage.
  • Prefer siprintf over sprintf, as it produces much smaller binaries by stripping out the floating point printing routines. Of course siprintf doesn't support floating point numbers, so if you need to print them and cannot use a fixed-point representation you'll have to live with the increased binary size.
  • C++ is supported, just name your C++ files with .cpp extensions. The C++ standard library is NOT (yet?) supported. It's really bulky and it hardly fits in the ROM/RAM space we have. Exception handling and RTTI are disabled.

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