620 lines
26 KiB
Plaintext
620 lines
26 KiB
Plaintext
README
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======
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This README discusses issues unique to NuttX configurations for the Spark Core board from Spark Devices (http://www.spark.io). This board features the STM32103CBT6 MCU from STMicro.
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Microprocessor: 32-bit ARM Cortex M3 at 72MHz STM32F103CBT6
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Memory: 120 KB Flash and 20 KB SRAM, 2M serial Flash
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I/O Pins Out: 37, 17 On the Connector
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Network: TI CC3000 Wifi Module
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ADCs: 9 (at 12-bit resolution)
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Peripherals: 4 timers, 2 I2Cs, 2 SPI ports, 3 USARTs, 2 led's one Blue and one RGB.
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Other: Sleep, stop, and standby modes; serial wire debug and JTAG interfaces
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During the development of the SparkCore, the hardware was in limited supply
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As a work around David Sidrane <david_s5@nscdg.com> created a SparkCore Big board
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(http://nscdg.com/spark/sparkBB.png) that will interface with a maple mini
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(http://leaflabs.com/docs/hardware/maple-mini.html), and a CC3000BOOST
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(https://estore.ti.com/CC3000BOOST-CC3000-BoosterPack-P4258.aspx)
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It breaks out the Tx, Rx to connect to a FTDI TTL-232RG-VREG3V3-WE for the console and
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wires in the spark LEDs and serial flash to the same I/O as the sparkcore. It has a Jlink
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compatible Jtag connector on it.
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Contents
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========
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- Development Environment
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- GNU Toolchain Options
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- IDEs
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- NuttX EABI "buildroot" Toolchain
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- NuttX OABI "buildroot" Toolchain
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- NXFLAT Toolchain
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- Hardware
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- Core Pin out
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- LEDs
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- Buttons
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- USARTS and Serial Consoles
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- DFU and JTAG
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- Spark -specific Configuration Options
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- Configurations
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Development Environment
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=======================
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Either Linux or Cygwin on Windows can be used for the development environment.
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The source has been built only using the GNU toolchain (see below). Other
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toolchains will likely cause problems.
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GNU Toolchain Options
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=====================
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Toolchain Configurations
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------------------------
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The NuttX make system has been modified to support the following different
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toolchain options.
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1. The CodeSourcery GNU toolchain,
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2. The Atollic Toolchain,
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3. The devkitARM GNU toolchain,
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4. Raisonance GNU toolchain, or
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5. The NuttX buildroot Toolchain (see below).
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All testing has been conducted using the CodeSourcery toolchain for Linux.
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To use the Atollic, devkitARM, Raisonance GNU, or NuttX buildroot toolchain,
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you simply need to add one of the following configuration options to your
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.config (or defconfig) file:
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CONFIG_ARMV7M_TOOLCHAIN_CODESOURCERYW=n : CodeSourcery under Windows
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CONFIG_ARMV7M_TOOLCHAIN_CODESOURCERYL=y : CodeSourcery under Linux
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CONFIG_ARMV7M_TOOLCHAIN_ATOLLIC=y : The Atollic toolchain under Windows
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CONFIG_ARMV7M_TOOLCHAIN_DEVKITARM=n : devkitARM under Windows
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CONFIG_ARMV7M_TOOLCHAIN_RAISONANCE=y : Raisonance RIDE7 under Windows
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CONFIG_ARMV7M_TOOLCHAIN_BUILDROOT=n : NuttX buildroot under Linux or Cygwin (default)
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If you change the default toolchain, then you may also have to modify the PATH in
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the setenv.h file if your make cannot find the tools.
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NOTE: the CodeSourcery (for Windows), Atollic, devkitARM, and Raisonance toolchains are
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Windows native toolchains. The CodeSourcey (for Linux) and NuttX buildroot
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toolchains are Cygwin and/or Linux native toolchains. There are several limitations
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to using a Windows based toolchain in a Cygwin environment. The three biggest are:
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1. The Windows toolchain cannot follow Cygwin paths. Path conversions are
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performed automatically in the Cygwin makefiles using the 'cygpath' utility
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but you might easily find some new path problems. If so, check out 'cygpath -w'
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2. Windows toolchains cannot follow Cygwin symbolic links. Many symbolic links
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are used in Nuttx (e.g., include/arch). The make system works around these
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problems for the Windows tools by copying directories instead of linking them.
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But this can also cause some confusion for you: For example, you may edit
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a file in a "linked" directory and find that your changes had no effect.
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That is because you are building the copy of the file in the "fake" symbolic
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directory. If you use a Windows toolchain, you should get in the habit of
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making like this:
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make clean_context all
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An alias in your .bashrc file might make that less painful.
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3. Dependencies are not made when using Windows versions of the GCC. This is
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because the dependencies are generated using Windows pathes which do not
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work with the Cygwin make.
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MKDEP = $(TOPDIR)/tools/mknulldeps.sh
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The CodeSourcery Toolchain (2009q1)
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-----------------------------------
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The CodeSourcery toolchain (2009q1) does not work with default optimization
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level of -Os (See Make.defs). It will work with -O0, -O1, or -O2, but not with
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-Os.
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The Atollic "Pro" and "Lite" Toolchain
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--------------------------------------
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One problem that I had with the Atollic toolchains is that the provide a gcc.exe
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and g++.exe in the same bin/ file as their ARM binaries. If the Atollic bin/ path
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appears in your PATH variable before /usr/bin, then you will get the wrong gcc
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when you try to build host executables. This will cause to strange, uninterpretable
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errors build some host binaries in tools/ when you first make.
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Also, the Atollic toolchains are the only toolchains that have built-in support for
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the FPU in these configurations. If you plan to use the Cortex-M4 FPU, you will
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need to use the Atollic toolchain for now. See the FPU section below for more
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information.
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The Atollic "Lite" Toolchain
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----------------------------
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The free, "Lite" version of the Atollic toolchain does not support C++ nor
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does it support ar, nm, objdump, or objdcopy. If you use the Atollic "Lite"
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toolchain, you will have to set:
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CONFIG_HAVE_CXX=n
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In order to compile successfully. Otherwise, you will get errors like:
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"C++ Compiler only available in TrueSTUDIO Professional"
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The make may then fail in some of the post link processing because of some of
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the other missing tools. The Make.defs file replaces the ar and nm with
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the default system x86 tool versions and these seem to work okay. Disable all
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of the following to avoid using objcopy:
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CONFIG_RRLOAD_BINARY=n
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CONFIG_INTELHEX_BINARY=n
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CONFIG_MOTOROLA_SREC=n
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CONFIG_RAW_BINARY=n
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devkitARM
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---------
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The devkitARM toolchain includes a version of MSYS make. Make sure that the
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the paths to Cygwin's /bin and /usr/bin directories appear BEFORE the devkitARM
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path or will get the wrong version of make.
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IDEs
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====
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NuttX is built using command-line make. It can be used with an IDE, but some
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effort will be required to create the project.
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Makefile Build
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--------------
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Under Eclipse, it is pretty easy to set up an "empty makefile project" and
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simply use the NuttX makefile to build the system. That is almost for free
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under Linux. Under Windows, you will need to set up the "Cygwin GCC" empty
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makefile project in order to work with Windows (Google for "Eclipse Cygwin" -
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there is a lot of help on the internet).
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Using Sourcery CodeBench from http://www.mentor.com/embedded-software/sourcery-tools/sourcery-codebench/overview
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Download and install the latest version (as of this writting it was
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sourceryg++-2013.05-64-arm-none-eabi)
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Import the project from git.
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File->import->Git-URI, then import a Exiting code as a Makefile progject
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from the working directory the git clone was done to.
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Select the Sourcery CodeBench for ARM EABI. N.B. You must do one command line
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build, before the make will work in CodeBench.
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Native Build
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------------
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Here are a few tips before you start that effort:
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1) Select the toolchain that you will be using in your .config file
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2) Start the NuttX build at least one time from the Cygwin command line
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before trying to create your project. This is necessary to create
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certain auto-generated files and directories that will be needed.
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3) Set up include pathes: You will need include/, arch/arm/src/stm32,
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arch/arm/src/common, arch/arm/src/armv7-m, and sched/.
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4) All assembly files need to have the definition option -D __ASSEMBLY__
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on the command line.
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Startup files will probably cause you some headaches. The NuttX startup file
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is arch/arm/src/stm32/stm32_vectors.S. With RIDE, I have to build NuttX
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one time from the Cygwin command line in order to obtain the pre-built
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startup object needed by RIDE.
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NuttX EABI "buildroot" Toolchain
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================================
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A GNU GCC-based toolchain is assumed. The files */setenv.sh should
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be modified to point to the correct path to the Cortex-M3 GCC toolchain (if
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different from the default in your PATH variable).
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If you have no Cortex-M3 toolchain, one can be downloaded from the NuttX
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SourceForge download site (https://sourceforge.net/projects/nuttx/files/buildroot/).
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This GNU toolchain builds and executes in the Linux or Cygwin environment.
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1. You must have already configured Nuttx in <some-dir>/nuttx.
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cd tools
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./configure.sh stm32_tiny/<sub-dir>
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2. Download the latest buildroot package into <some-dir>
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3. unpack the buildroot tarball. The resulting directory may
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have versioning information on it like buildroot-x.y.z. If so,
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rename <some-dir>/buildroot-x.y.z to <some-dir>/buildroot.
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4. cd <some-dir>/buildroot
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5. cp configs/cortexm3-eabi-defconfig-4.6.3 .config
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6. make oldconfig
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7. make
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8. Edit setenv.h, if necessary, so that the PATH variable includes
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the path to the newly built binaries.
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See the file configs/README.txt in the buildroot source tree. That has more
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details PLUS some special instructions that you will need to follow if you are
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building a Cortex-M3 toolchain for Cygwin under Windows.
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NOTE: Unfortunately, the 4.6.3 EABI toolchain is not compatible with the
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the NXFLAT tools. See the top-level TODO file (under "Binary loaders") for
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more information about this problem. If you plan to use NXFLAT, please do not
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use the GCC 4.6.3 EABI toochain; instead use the GCC 4.3.3 OABI toolchain.
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See instructions below.
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NuttX OABI "buildroot" Toolchain
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================================
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The older, OABI buildroot toolchain is also available. To use the OABI
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toolchain:
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1. When building the buildroot toolchain, either (1) modify the cortexm3-eabi-defconfig-4.6.3
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configuration to use EABI (using 'make menuconfig'), or (2) use an exising OABI
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configuration such as cortexm3-defconfig-4.3.3
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2. Modify the Make.defs file to use the OABI conventions:
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+CROSSDEV = arm-nuttx-elf-
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+ARCHCPUFLAGS = -mtune=cortex-m3 -march=armv7-m -mfloat-abi=soft
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+NXFLATLDFLAGS2 = $(NXFLATLDFLAGS1) -T$(TOPDIR)/binfmt/libnxflat/gnu-nxflat-gotoff.ld -no-check-sections
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-CROSSDEV = arm-nuttx-eabi-
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-ARCHCPUFLAGS = -mcpu=cortex-m3 -mthumb -mfloat-abi=soft
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-NXFLATLDFLAGS2 = $(NXFLATLDFLAGS1) -T$(TOPDIR)/binfmt/libnxflat/gnu-nxflat-pcrel.ld -no-check-sections
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NXFLAT Toolchain
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================
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If you are *not* using the NuttX buildroot toolchain and you want to use
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the NXFLAT tools, then you will still have to build a portion of the buildroot
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tools -- just the NXFLAT tools. The buildroot with the NXFLAT tools can
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be downloaded from the NuttX SourceForge download site
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(https://sourceforge.net/projects/nuttx/files/).
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This GNU toolchain builds and executes in the Linux or Cygwin environment.
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1. You must have already configured Nuttx in <some-dir>/nuttx.
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cd tools
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./configure.sh lpcxpresso-lpc1768/<sub-dir>
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2. Download the latest buildroot package into <some-dir>
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3. unpack the buildroot tarball. The resulting directory may
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have versioning information on it like buildroot-x.y.z. If so,
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rename <some-dir>/buildroot-x.y.z to <some-dir>/buildroot.
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4. cd <some-dir>/buildroot
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5. cp configs/cortexm3-defconfig-nxflat .config
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6. make oldconfig
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7. make
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8. Edit setenv.h, if necessary, so that the PATH variable includes
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the path to the newly builtNXFLAT binaries.
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DFU and JTAG
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============
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Enbling Support for the DFU Bootloader
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--------------------------------------
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The linker files in these projects can be configured to indicate that you
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will be loading code using STMicro built-in USB Device Firmware Upgrade (DFU)
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loader or via some JTAG emulator. You can specify the DFU bootloader by
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adding the following line:
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CONFIG_STM32_DFU=y
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to your .config file. Most of the configurations in this directory are set
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up to use the DFU loader.
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If CONFIG_STM32_DFU is defined, the code will not be positioned at the beginning
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of FLASH (0x08000000) but will be offset to 0x08005000. This offset is needed
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to make space for the DFU loader and 0x08005000 is where the DFU loader expects
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to find new applications at boot time. If you need to change that origin for some
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other bootloader, you will need to edit the file(s) ld.script.dfu for the
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configuration.
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For Linux or Mac:
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----------------
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While on Linux or Mac, we can use dfu-util to upload nuttx binary.
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1. Make sure we have installed dfu-util. (From yum, apt-get or build from source.)
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2. Start the DFU loader (bootloader) on the Spark board. You do this by
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resetting the board while holding the "Key" button. Windows should
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recognize that the DFU loader has been installed.
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3. Flash the nuttx.bin to the board use dfu-util. Here's an example:
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$ dfu-util -a1 -d 1eaf:0003 -D nuttx.bin -R
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For anything not clear, we can refer to LeafLabs official document:
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http://leaflabs.com/docs/unix-toolchain.html
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For Windows:
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-----------
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The DFU SE PC-based software is available from the STMicro website,
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http://www.st.com. General usage instructions:
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1. Convert the NuttX Intel Hex file (nuttx.hex) into a special DFU
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file (nuttx.dfu)... see below for details.
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2. Connect the M3 Wildfire board to your computer using a USB
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cable.
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3. Start the DFU loader on the M3 Wildfire board. You do this by
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resetting the board while holding the "Key" button. Windows should
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recognize that the DFU loader has been installed.
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3. Run the DFU SE program to load nuttx.dfu into FLASH.
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What if the DFU loader is not in FLASH? The loader code is available
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inside of the Demo dirctory of the USBLib ZIP file that can be downloaded
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from the STMicro Website. You can build it using RIDE (or other toolchains);
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you will need a JTAG emulator to burn it into FLASH the first time.
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In order to use STMicro's built-in DFU loader, you will have to get
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the NuttX binary into a special format with a .dfu extension. The
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DFU SE PC_based software installation includes a file "DFU File Manager"
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conversion program that a file in Intel Hex format to the special DFU
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format. When you successfully build NuttX, you will find a file called
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nutt.hex in the top-level directory. That is the file that you should
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provide to the DFU File Manager. You will end up with a file called
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nuttx.dfu that you can use with the STMicro DFU SE program.
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Enabling JTAG
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-------------
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If you are not using the DFU, then you will probably also need to enable
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JTAG support. By default, all JTAG support is disabled but there NuttX
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configuration options to enable JTAG in various different ways.
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These configurations effect the setting of the SWJ_CFG[2:0] bits in the AFIO
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MAPR register. These bits are used to configure the SWJ and trace alternate function I/Os.
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The SWJ (SerialWire JTAG) supports JTAG or SWD access to the Cortex debug port.
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The default state in this port is for all JTAG support to be disable.
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CONFIG_STM32_JTAG_FULL_ENABLE - sets SWJ_CFG[2:0] to 000 which enables full
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SWJ (JTAG-DP + SW-DP)
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CONFIG_STM32_JTAG_NOJNTRST_ENABLE - sets SWJ_CFG[2:0] to 001 which enable
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full SWJ (JTAG-DP + SW-DP) but without JNTRST.
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CONFIG_STM32_JTAG_SW_ENABLE - sets SWJ_CFG[2:0] to 010 which would set JTAG-DP
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disabled and SW-DP enabled
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The default setting (none of the above defined) is SWJ_CFG[2:0] set to 100
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which disable JTAG-DP and SW-DP.
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Hardware
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========
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The Spark comprises a STM32F103CB 72 Mhz, 128 Flash, 20K Ram, with 37 IO Pins, and
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a TI CC3000 Wifi Module. It has a 2MB serial flash, onboad regulation and 2 led's
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one Blue and one RGB.
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During the development of the SparkCore, the hardware was in limited supply
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As a work around david_s5 created a SparkCore Big board (http://nscdg.com/spark/sparkBB.png)
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that will interface with a maple mini (http://leaflabs.com/docs/hardware/maple-mini.html),
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and a CC3000BOOST (https://estore.ti.com/CC3000BOOST-CC3000-BoosterPack-P4258.aspx)
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It breaks out the Tx, Rx to connect to a FTDI TTL-232RG-VREG3V3-WE for the console and
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wires in the spark LEDs and serial flash to the same I/O as the sparkcore. It has a Jlink
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compatible Jtag connector on it.
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Core Pin out
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============
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There are 24 pis on the Spark Core module.
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Spark Spark Function STM32F103CBT6
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Name Pin # Pin #
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-------- ------ ------------------------------------------------ ---------------
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RAW JP1-1 Input Power N/A
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GND JP1-2 GND
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TX JP1-3 PA[02] USART2_TX/ADC12_IN2/TIM2_CH3 12
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RX JP1-4 PA[03] USART2_RX/ADC12_IN3/TIM2_CH4 13
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A7 JP1-5 PB[01] ADC12_IN9/TIM3_CH4 19
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A6 JP1-6 PB[00] ADC12_IN8/TIM3_CH3 18
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A5 JP1-7 PA[07] SPI1_MOSI/ADC12_IN7/TIM3_CH2 17
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A4 JP1-8 PA[06] SPI1_MISO/ADC12_IN6/TIM3_CH1 16
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A3 JP1-9 PA[05] SPI1_SCK/ADC12_IN5 15
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A2 JP1-10 PA[04] SPI1_NSS/USART2_CK/ADC12_IN4 14
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A1 JP1-11 PA[01] USART2_RTS/ADC12_IN1/TIM2_CH2 11
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A0 JP1-12 PA[00] WKUP/USART2_CTS/ADC12_IN0/TIM2_CH1_ETR 10
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+3V3 JP2-1 V3.3 Out of Core NA
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RST JP2-2 NRST 7
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VDDA JP2-3 ADC Voltage 9
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GND JP2-4 GND
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D7 JP2-5 PA[13] JTMS/SWDIO 34 Common with Blue LED LED_USR
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D6 JP2-6 PA[14] JTCK/SWCLK 37
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D5 JP2-7 PA[15] JTDI 38
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D4 JP2-8 PB[03] JTDO 39
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D3 JP2-9 PB[04] NJTRST 40
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D2 JP2-10 PB[05] I2C1_SMBA 41
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D1 JP2-11 PB[06] I2C1_SCL/TIM4_CH1 42
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D0 JP2-12 PB[07] I2C1_SDA/TIM4_CH2 43
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Core Internal IO
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================
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Spark Function STM32F103CBT6
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Name Pin #
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-------- ------------------------------------------------ ---------------
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BTN PB[02] BOOT1 20
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LED1,D7 PA[13] JTMS/SWDIO 34
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LED2 PA[08] USART1_CK/TIM1_CH1/MCO 29
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LED3 PA[09] USART1_TX/TIM1_CH2 30
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LED4 PA[10] USART1_RX/TIM1_CH3 31
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MEM_CS PB[09] TIM4_CH4 46 SST25VF016B Chip Select
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SPI_CLK PB[13] SPI2_SCK/USART3_CTS/TIM1_CH1N 26
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SPI_MISO PB[14] SPI2_MISO/USART3_RTS/TIM1_CH2N 27
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SPI_MOSI PB[15] SPI2_MOSI/TIM1_CH3N 28
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USB_DISC PB[10] I2C2_SCL/USART3_TX 21
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WIFI_CS PB[12] SPI2_NSS/I2C2_SMBA/USART3_CK/TIM1_BKIN 25 CC3000 Chip Select
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WIFI_EN PB[08] TIM4_CH3 45 CC3000 Module enable
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WIFI_INT PB[11] I2C2_SDA/USART3_RX 22 CC3000 Host interface SPI interrupt
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Buttons and LEDs
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================
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Buttons
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-------
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The Spark has two mechanical buttons. One button is the RESET button
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connected to the STM32F103CB's reset line via /RST and the other is a
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generic user configurable button labeled BTN and connected to GPIO
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PB2/BOOT1. Since on the Spark, BOOT0 is tied to GND it is a moot point
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that BTN signal is connected to the BOOT1 signal. When a button is
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pressed it will drive the I/O line to GND.
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LEDs
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----
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There are 4 user-controllable LEDs in two packages on board the Spark board:
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Sigal Location Color GPIO Active
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------- ------------ ----------- ----- -----------
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LED1 LED_USR Blue LED PA13 High Common With D7
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LED2 LED_RGB Red LED PA8 Low
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LED3 LED_RGB Blue LED PA9 Low
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LED4 LED_RGB Green LED PA10 Low
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LED1 is connected to ground and can be illuminated by driving the PA13
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output high, it shares the Sparks D7 output. The LED2,LED3 and LED4
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are pulled high and can be illuminated by driving the corresponding GPIO output
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to low.
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The RGB LEDs are not used by the board port unless CONFIG_ARCH_LEDS is
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defined. In that case, the usage by the board port is defined in
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include/board.h and src/up_leds.c. The LEDs are used to encode OS-related
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events as follows:
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SYMBOL Meaning LED2 LED3 LED4
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red blue green Color
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------------------- ----------------------- ------- ------- ------ ---------
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LED_STARTED NuttX has been started ON OFF OFF Red
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LED_HEAPALLOCATE Heap has been allocated OFF ON OFF Blue
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LED_IRQSENABLED Interrupts enabled ON OFF ON Orange
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LED_STACKCREATED Idle stack created OFF OFF ON Green
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LED_INIRQ In an interrupt** ON N/C N/C Orange Glow
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LED_SIGNAL In a signal handler*** N/C ON N/C Blue Glow
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LED_ASSERTION An assertion failed ON ON ON White
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LED_PANIC The system has crashed ON N/C N/C Red Flashing
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LED_IDLE STM32 is is sleep mode (Optional, not used)
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* If LED2, LED3, LED4 are statically on, then NuttX probably failed to boot
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and these LEDs will give you some indication of where the failure was
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** The normal state is LED4 ON and LED2 faintly glowing. This faint glow
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is because of timer interrupts that result in the LED being illuminated
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on a small proportion of the time.
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*** LED3 may also flicker normally if signals are processed.
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Serial Consoles
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===============
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USART2
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-----
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If you have a 3.3 V TTL to RS-232 convertor then this is the most convenient
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serial console to use. UART2 is the default in all of these
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configurations.
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USART2 RX PA3 JP1 pin 4
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USART2 TX PA2 JP1 pin 3
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GND JP1 pin 2
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V3.3 JP2 pin 1
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Virtual COM Port
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----------------
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Yet another option is to use UART0 and the USB virtual COM port. This
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option may be more convenient for long term development, but was
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painful to use during board bring-up.
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Spark -specific Configuration Options
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==============
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WIP
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Configurations
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==============
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Composite: The composite is a super set of all the functions in nsh,
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usbserial, usbmsc. (usbnsh has not been rung out).
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Build it with
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make distclean;cd tools;./configure.sh spark/composite;cd ..
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then run make menuconfig if you wish to customize things.
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N.B. Memory is tight, both Flash and RAM are taxed. If you enable
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debugging you will need to add -Os following the line -g in the line:
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ifeq ($(CONFIG_DEBUG_SYMBOLS),y)
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ARCHOPTIMIZATION = -g
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in the top level Make.degs or the code will not fit.
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Stack space has been hand optimized using the stack coloring by enabling
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"Stack coloration" (CONFIG_STACK_COLORATION) in Build Setup-> Debug
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Options. I have selected values that have 8-16 bytes of headroom with
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network debugging on. If you enable more debugging and get a hard fault
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or any weirdness like commands hanging. Then the Idle, main or Interrupt
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stack my be too small. Stop the target and have a look a memory for a
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blown stack: No DEADBEEF at the lowest address of a given stack.
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Given the RAM memory constraints it is not possible to be running the
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network and USB CDC/ACM and MSC at the same time. But on the bright
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side, you can export the FLASH memory to the PC. Write files on the
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Flash. Reboot and mount the FAT FS and run network code that will have
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access the files.
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You can use the scripts/cdc-acm.inf file to install the windows
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composite device.
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SPI2 is enabled and support is included for the FAT file system on the
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16Mbit (2M) SST25 device and control of the CC3000 on the spark core.
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When the system boots, you should have a dev/mtdblock0 that can be
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mounted using the command:
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mount -t vfat /dev/mtdblock0 /mnt/p0
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or /dev/mtdblock0 can be exported as MSC on the USB interface along with
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a Virtual serial port as a CDC/ACM interface.
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Use the command conn* and disconn to manage the USB interface.
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N.B. *If /dev/mtdblock0 is mounted then You must unmount it prior to
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exporting it via the conn command. Bad things will happen if not.
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Network control is facilitated by running the c3b (cc3000basic) application.
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Run c3b from the nsh prompt.
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+-------------------------------------------+
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| Nuttx CC3000 Demo Program |
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+-------------------------------------------+
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01 - Initialize the CC3000
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02 - Show RX & TX buffer sizes, & free RAM
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03 - Start Smart Config
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04 - Manually connect to AP
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05 - Manually add connection profile
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06 - List access points
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07 - Show CC3000 information
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08 - Telnet
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Type 01-07 to select above option:
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Select 01. Then use 03 and the TI Smart config application running on an
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IOS or Android device to configure join your network.
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Use 07 to see the IP address of the device.
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(On the next reboot running c3b 01 the CC3000 will automaticaly rejoin the
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network after the 01 give it a few seconds and enter 07 or 08)
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Use 08 to start Telnet. Then you can connect to the device using the
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address listed in command 07.
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qq will exit the c3b with the telnet deamon running (if started)
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Slow.... You will be thinking 300 bps. This is because of packet sizes and
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how the select thread runs in the telnet session. Telnet is not the best
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showcase for the CC3000, but simply a proof of network connectivity.
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http POST and GET should be more efficient.
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