034d5ffcdb
git-svn-id: svn://svn.code.sf.net/p/nuttx/code/trunk@2653 42af7a65-404d-4744-a932-0658087f49c3
436 lines
16 KiB
Plaintext
436 lines
16 KiB
Plaintext
README File for the Olimex STR-P711 NuttX Port
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Contents
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^^^^^^^^
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Olimex STR-P711
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Features
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Power Supply
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GIO Usage
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Jumpers
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External Interrupts
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Development Environment
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GNU Toolchain Options
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NuttX buildroot Toolchain
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Linux OpenOCD with Wiggler JTAG
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Windows OpenOCD will Olimex JTAG
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MMC/SD Slot
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ENC28J60 Module
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Configurations
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STR71x-Specific Configuration Settings
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Olimex STR-P711
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^^^^^^^^^^^^^^^
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Features:
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- MCU: STR711FR2T6 16/32 bit ARM7TDMI™ with 256K Bytes Program Flash,
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64K Bytes RAM, USB 2.0, RTC, 12 bit ADC, 4x UARTs, 2x I2C,2x SPI,
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5x 32bit TIMERS, 2x PWM, 2x CCR, WDT, up to 50MHz operation
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- Standard JTAG connector with ARM 2x10 pin layout for programming/debugging
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with ARM-JTAG
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- USB connector
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- Two channel RS232 interface and drivers
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- SD/MMC card connector
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- Two buttons
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- Trimpot connected to ADC
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- Two status LEDs
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- Buzzer
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- UEXT - 10 pin extension connector for Olimex addon peripherials like MP3,
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RF2.4Ghz, RFID etc. modules
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- 2x SPI connectors
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- I2C connector
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- On board voltage regulator 3.3V with up to 800mA current
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- Single power supply: 6V AC or DC required, USB port can power the board
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- Power supply LED
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- Power supply filtering capacitor
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- RESET circuit
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- RESET button
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- 4 Mhz crystal oscillator
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- 32768 Hz crystal and RTC
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Power Supply
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6V AC or DC (or powered from USB port)
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GIO with on-board connections (others available for prototyping):
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SIGNAL DESCRIPTION PIN
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------- --------------------- -----
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MISO1 BSPI0 to MMC/SD P0.4
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MOSI1 " " "" " " P0.5
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SCLK1 " " "" " " P0.6
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SS1 " " "" " " P0.7
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U0RX UART 0 P0.8
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U0TX " " " P0.9
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U1RX UART 1 P0.10
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U1TX " " " P0.11
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BUZZ Buzzer P0.13
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WAKE-UP Button P0.15
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AIN0 Potentiometer (AN_TR) P1.3
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LED1 LED 1 P1.8
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LED2 LED 2 P1.9
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WP MMC/SD write protect P1.10
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USBOP USB P1.11
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USBON " " P1.12
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BUT Button P1.13
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CP MMC/SD card present P1.15
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Jumpers
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STNBY Will pull pin 23 /STDBY low
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External Interrupt (XTI) availability.
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XTI TQFP64
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LINE PIN SIGNAL * OLIMEX USAGE
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---- ------ ------------------------- - ------------------------
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2 -- P2.8 (Not available in TQFP64)
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3 -- P2.9 (Not available in TQFP64)
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4 -- P2.10 (Not available in TQFP64)
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5 25 P2.11 (Not available in TQFP64)
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6 42 P1.11/CANRX USBOP (to USB connector)
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7 47 P1.13/HCLK/I0.SCL CLK ??????????????
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8 48 P1.14/HRXD/I0.SDA BUT button (PL open, PU closed)
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9 53 P0.1/S0.MOSI/U3.RX * SPI0-3 MOSI0
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10 54 P0.2/S0.SCLK/I1.SCL * SPI0-5 SCLK0
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11 61 P0.6/S1.SCLK * SPI1-5 SCLK1 (also to MMC slot)
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12 63 P0.8/U0.RX/U0.TX U0.TX
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13 1 P0.10/U1.RX/U1.TX/SC.DATA U1.RX
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14 5 P0.13/U2.RX/T2.OCMPA BUZZ (to buzzer circult)
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15 20 P0.15/WAKEUP WAKE-UP button (PL open, PU closed)
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* Only these pins are available at a
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connector and are not dedicated to
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other board functions.
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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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The NuttX make system has been modified to support the following different
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toolchain options.
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1. The NuttX buildroot Toolchain (see below).
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2. The CodeSourcery GNU toolchain,
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3. The devkitARM GNU toolchain, or
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All testing has been conducted using the NuttX buildroot toolchain. To use
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the CodeSourcery or devkitARM GNU toolchain, you simply need to build the
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system as follows:
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make # Will build for the NuttX buildroot toolchain
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make CROSSDEV=arm-eabi- # Will build for the devkitARM toolchain
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make CROSSDEV=arm-none-eabi- # Will build for the CodeSourcery toolchain
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make CROSSDEV=arm-elf- # Will build for the NuttX buildroot toolchain
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Of course, hard coding this CROSS_COMPILE value in Make.defs file will save
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some repetitive typing.
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NOTE: the CodeSourcery and devkitARM toolchains are Windows native toolchains.
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The NuttX buildroot toolchain is a Cygwin toolchain. 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 not 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; make CROSSDEV=arm-none-eabi-
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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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Support has been added for making dependencies with the CodeSourcery toolchain.
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That support can be enabled by modifying your Make.defs file as follows:
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- MKDEP = $(TOPDIR)/tools/mknulldeps.sh
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+ MKDEP = $(TOPDIR)/tools/mkdeps.sh --winpaths "$(TOPDIR)"
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If you have problems with the dependency build (for example, if you are not
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building on C:), then you may need to modify tools/mkdeps.sh
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NOTE 1: The CodeSourcery toolchain (2009q1) may 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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NOTE 2: The devkitARM toolchain includes a version of MSYS make. Make sure that
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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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NuttX 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 ARM toolchain (if
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different from the default).
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If you have no ARM toolchain, one can be downloaded from the NuttX
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SourceForge download site (https://sourceforge.net/project/showfiles.php?group_id=189573).
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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 olimex-strp711/<sub-dir>
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2. Download the latest buildroot package into <some-dir>
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3. unpack
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4. cd <some-dir>/buildroot
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5. cp configs/arm-defconfig .config
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or
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cp configs/arm7tdmi-defconfig-4.3.3 .config (Last tested with this toolchain)
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6. make oldconfig
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7. make
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8. Edit setenv.h so that the PATH variable includes the path to the
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newly built binaries.
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Linux OpenOCD with Wiggler JTAG
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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For a debug environment, I am using OpenOCD with a Wiggler-clone JTAG interface. The
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following steps worked for me with a 20081028 OpenOCD snapshot.
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GENERAL STEPS:
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1. Check out OpenOCD
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svn checkout svn://svn.berlios.de/openocd/trunk openocd
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2. Build OpenOCD
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Read the INSTALL file from the files you just downloaded. You probably just need
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to run:
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./bootstrap
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Then configure OpenOCD using the configure script created by ./bootstrap.
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./configure --enable-parport
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Build OpenOCD with:
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make
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Install OpenOCD. Since we used the default configuration the code will be
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installed at /usr/local/bin/openocd. Other files will be installed at
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/usr/local/lib/openocd (configuration files, scripts, etc.) and /usr/local/share/info
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(online documentation accessable via 'info openocd'). You need root priviledges
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to do the following:
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make install.
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3. Setup
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OpenOCD reads its configuration from the file openocd.cfg in the current directory
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when started. You have two different options:
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* Create a symbolic link named openocd.cfg to one of the configuration files in
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/usr/local/lib/openocd, or
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* Use a custom configuration file specified with the ‘-f <conf.file>’ command line
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switch opeion when starting OpenOCD.
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For the STR-P711, I have included bash scripts in the scripts sub-directory.
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4. Running OpenOCD
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Make sure the ARM7TDMI board is powered and the JTAG cable is connected
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Run 'src/openocd -d' (might be required to be root) and check for any errors
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reported. The '-d' option enables debugging info.
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5. Telnet interface
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telnet into port 4444 to get a command interface: 'telnet localhost 4444'
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6. GDB
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start arm-elf-gdb
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type 'file <executable.elf>' to load the executable
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type 'set debug remote 1' to enable tracing of gdb protocol (if required)
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type 'target remote localhost:3333' to connect to the target
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The same commands from the telnet interface can now be accessed through the
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'monitor' command, e.g. 'monitor help'
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Windows OpenOCD will Olimex JTAG
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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I have been using the Olimex ARM-USB-OCD JTAG debugger with the STR-P711
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(http://www.olimex.com). The OpenOCD configuration file is here:
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scripts/oocd_ft2xx.cfg. There is also a script on the scripts/ directory that
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I used to start the OpenOCD daemon on my system called oocd.sh. That
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script would probably require some modifications to work in another
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environment:
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- possibly the value of OPENOCD_PATH
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- If you are working under Linux you will need to change any
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occurances of `cygpath -w blablabla` to just blablabla
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The setenv.sh file includes some environment varialble settings
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that are needed by oocd.sh. If you have $PATH and other environment
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variables set up, then you should be able to start the OpenOCD daemon like:
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oocd.sh
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To use the Windows Olimex USB JTAG (or 'oocd.sh pp' to use the Wriggler
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JTAG) where it is assumed that you are executing oocd.sh from the top level
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level NuttX directory.
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Once the OpenOCD daemon has been started, you can connect to it via
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GDB using the following GDB command:
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arm-elf-gdb
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(gdb) target remote localhost:3333
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And you can load the NuttX ELF file into FLASH:
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(gdb) load nuttx
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(There are also some files in the scripts/ directory that I used to
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get OpenOCD working with a Wriggler clone... I never got that stuff
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working).
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MMC/SD Slot
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^^^^^^^^^^^
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STR-P711 PIN MMC/SD USAGE PIN CONFIGURATION
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------------ ---------------- -----------------------
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P0.7/S1.SS 1 CD/DAT3/CS P.07 output
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P0.5/S1.MOSI 2 CMD/DI MOSI1
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--- 3 VSS1 ---
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--- 4 VDD ---
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P0.6/S1.SCLK 5 CLK/SCLK SLCK1
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--- 6 VSS2 ---
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P0.4/S1.MISO 7 DAT0/D0 MISO1
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--- 8 DAT1/RES (Pulled up)
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--- 9 DAT2/RES (Pulled up)
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P1.10/USBCLK 10/14 WP P1.10 input
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P1.15/HTXD 13/15 CP P1.15 input
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Use of SPI1 doesn't conflict with anything. WP conflicts USB; CP conflicts
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with NTXD.
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ENC28J60 Module
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^^^^^^^^^^^^^^^
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The ENC28J60 module does not come on the Olimex-STR-P711, but this describes
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how I have connected it. NOTE that the ENC28J60 requires an external interrupt
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(XTI) pin. The only easily accessible XTI pins are on SPI0/1 so you can't have
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both SPI0 and 1 together with this configuration.
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Module CON5 QFN ENC2860 Description
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--------------- -------------------------------------------------------
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1 J8-1 NET CS 5 ~CS Chip select input pin for SPI interface (active low)
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2 2 SCK 4 SCK Clock in pin for SPI interface
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3 3 MOSI 3 SI Data in pin for SPI interface
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4 4 MISO 2 SO Data out pin for SPI interface
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5 5 GND -- --- ---
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10 J9-1 3V3 -- --- ---
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9 2 WOL 1 ~WOL Unicast WOL filter
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8 3 NET INT 28 ~INT Interrupt output pin (active low)
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7 4 CLKOUT 27 CLKOUT Programmable clock output pin
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6 5 NET RST 6 ~RESET Active-low device Reset input
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For the Olimex STR-P711, the ENC28J60 module is placed on SPI0 and uses
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P0.3 for CS, P0.6 for an interrupt, and P0.4 as a reset:
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Module CON5 Olimex STR-P711 Connection
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--------------- -------------------------------------------------------
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1 J8-1 NET CS SPI0-2 P0.3 output P0.3/S0.SS/I1.SDA
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2 2 SCK SPI0-5 SCLK0 P0.2/S0.SCLK/I1.SCL
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3 3 MOSI SPI0-3 MOSI0 P0.0/S0.MOSI/U3.RX
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4 4 MISO SPI0-4 MISO0 P0.1/S0.MISO/U3.TX
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5 5 GND SPI0-1 GND
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10 J9-1 3V3 SPI0-6 3.3V
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9 2 WOL NC
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8 3 NET INT SPI1-5 P0.6 XTI 11 P0.6/S1.SCLK
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7 4 CLKOUT NC
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6 5 NET RST SPI1-4 P0.4 output P0.4/S1.MISO
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UART3, I2C cannot be used with SPI0. The GPIOs selected for the ENC28J60
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interrupt conflict with TIM1.
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NOTE: As of this writing, the ENC28J60 does not function on the board.
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The board just locks up when the ENC29J60 is powered. Most likely,
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in sufficient current is provided via USB to power both the board and
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the ENC28J60 (And I don't have the correct wall wart to power the
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the board).
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Configurations:
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---------------
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nettest:
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This configuration directory may be used to enable networking using the
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an Microchip ENC28J60 SPI ethernet module (see above for connection to
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STR-P711.
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nsh:
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Configures the NuttShell (nsh) located at examples/nsh. The
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Configuration enables both the serial and telnetd NSH interfaces.
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ostest:
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This configuration directory, performs a simple OS test using
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examples/ostest.
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STR71x-Specific Configuration Settings
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--------------------------------------
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CONFIG_STR71X_I2C0, CONFIG_STR71X_I2C1, CONFIG_STR71X_UART0, CONFIG_STR71X_UART1,
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CONFIG_STR71X_UART2, CONFIG_STR71X_UART3, CONFIG_STR71X_USB, CONFIG_STR71X_CAN,
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CONFIG_STR71X_BSPI0, CONFIG_STR71X_BSPI1, CONFIG_STR71X_HDLC, CONFIG_STR71X_XTI,
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CONFIG_STR71X_GPIO0, CONFIG_STR71X_GPIO1, CONFIG_STR71X_GPIO2, CONFIG_STR71X_ADC12,
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CONFIG_STR71X_CKOUT, CONFIG_STR71X_TIM1, CONFIG_STR71X_TIM2, CONFIG_STR71X_TIM3, and
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CONFIG_STR71X_RTC
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Select peripherals to initialize (Timer0 and EIC are always initialized)
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CONFIG_UART_PRI, STR71X_BSPI_PRI, CONFIG_TIM_PRI, CONFIG_USB_PRI
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Can be defined to set the priority of NuttX managed devices. Default is 1.
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CONFIG_STR71X_BANK0, CONFIG_STR71X_BANK1, CONFIG_STR71X_BANK2, and CONFIG_STR71X_BANK3
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Enable initialize of external memory banks 0-3.
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CONFIG_STR71X_BANK0_SIZE, CONFIG_STR71X_BANK1_SIZE, CONFIG_STR71X_BANK2_SIZE, and
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CONFIG_STR71X_BANK3_SIZE
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If a particular external memory bank is configured, then its width must be provided.
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8 and 16 (bits) are the only valid options.
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CONFIG_STR71X_BANK0_WAITSTATES, CONFIG_STR71X_BANK1_WAITSTATES,
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CONFIG_STR71X_BANK2_WAITSTATES, and CONFIG_STR71X_BANK3_WAITSTATES
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If a particular external memory bank is configured, then the number of waistates
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for the bank must also be provided. Valid options are {0, .., 15}
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CONFIG_STR71X_BIGEXTMEM
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The default is to provide 20 bits of address for all external memory regions. If
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any memory region is larger than 1Mb, then this option should be selected. In this
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case, 24 bits of addressing will be used
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CONFIG_UARTn_SERIAL_CONSOLE - selects the UARTn for the
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console and ttys0 (default is the UART0).
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CONFIG_UARTn_RXBUFSIZE - Characters are buffered as received.
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This specific the size of the receive buffer
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CONFIG_UARTn_TXBUFSIZE - Characters are buffered before
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being sent. This specific the size of the transmit buffer
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CONFIG_UARTn_BAUD - The configure BAUD of the UART. Must be
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CONFIG_UARTn_BITS - The number of bits. Must be either 7 or 8.
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CONFIG_UARTn_PARTIY - 0=no parity, 1=odd parity, 2=even parity, 3=mark 1, 4=space 0
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CONFIG_UARTn_2STOP - Two stop bits
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