622 lines
20 KiB
Plaintext
622 lines
20 KiB
Plaintext
README.txt
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==========
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This directory holds a port of NuttX to the NXP/Freescale Sabre board
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featuring the iMX 6Quad CPU.
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Contents
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========
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- Status
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- Platform Features
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- Serial Console
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- LEDs and Buttons
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- Using U-Boot to Run NuttX
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- Debugging with the Segger J-Link
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- SMP
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- Configurations
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Status
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======
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2016-02-28: The i.MX6Q port is just beginning. A few files have been
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populated with the port is a long way from being complete or even ready to
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begin any kind of testing.
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2016-03-12: The i.MX6Q port is code complete including initial
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implementation of logic needed for CONFIG_SMP=y . There is no clock
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configuration logic. This is probably not an issue if we are loaded into
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SDRAM by a bootloader (because we cannot change the clocking anyway in
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that case).
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There is a lot of testing that could be done but, unfortunately, I still
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have no i.MX6 hardware to test on.
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In additional to the unexpected issues, I do expect to run into some
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cache coherency issues when I get to testing an SMP configuration.
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2016-03-28: I now have a used MCIMX6Q-SDB which is similar to the target
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configuration described below except that it does not have the 10.1" LVDS
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display. Next step: Figure out how to run a copy of NuttX using U-Boot.
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2016-03-31: Most all of the boot of the NSH configuration seems to be
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working. It gets to NSH and NSH appears to run normally. Non-interrupt
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driver serial output to the VCOM console is working (llsyslog). However,
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there does not appear to be any interrupt activity: No timer interrupts,
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no interrupt driver serial console output (syslog, printf).
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2016-05-16: I now get serial interrupts (but not timer interrupts). This
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involves a few changes to GIC bit settings that I do not fully understand.
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With this change, the NSH serial console works:
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MX6Q SABRESD U-Boot > ABEFGHILMN
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NuttShell (NSH)
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nsh>
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But there are still no timer interrupts. LEDs do not appear to be working.
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2016-05-17: Timer interrupts now work. This turned out to be just a minor
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bit setting error in the timer configuration. LEDs were not working simply
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because board_autoled_initialize() was not being called in the board startup
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logic.
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At this point, I would say that the basic NSH port is complete.
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2016-05-18: Started looking at the SMP configuration. Initially, I verfied
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that the NSH configuration works with CONFIG_SMP_NCPUS=1. Not a very
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interesting case, but this does exercise a lot of the basic SMP logic.
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When more than one CPU is configured, then there are certain failures that
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appear to be stack corruption problem. See the open issues below under
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SMP.
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2016-05-22: In a simple NSH case, SMP does not seem to be working. But there
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are known SMP open issues so I assume if the tasking were stressed more there
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would be additional failures. See the open issues below under SMP.
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An smp configuration was added. This is not quite the same as the
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configuration that I used for testing. I enabled DEBUG output, ran with
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only 2 CPUS, and disabled the RAMLOG:
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+CONFIG_DEBUG_FEATURES=y
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+CONFIG_DEBUG_INFO=y
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+CONFIG_DEBUG_SCHED=y
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+CONFIG_DEBUG_SYMBOLS=y
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-CONFIG_DEBUG_FULLOPT=y
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+CONFIG_DEBUG_NOOPT=y
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-CONFIG_SMP_NCPUS=4
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+CONFIG_SMP_NCPUS=2
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-CONFIG_RAMLOG=y
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-CONFIG_RAMLOG_SYSLOG=y
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-CONFIG_RAMLOG_BUFSIZE=16384
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-CONFIG_RAMLOG_NONBLOCKING=y
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-CONFIG_RAMLOG_NPOLLWAITERS=4
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I would also disable debug output from CPU0 so that I could better see the
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debug output from CPU1. In drivers/syslog/vsyslog.c:
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+if (up_cpu_index() == 0) return 17; // REMOVE ME
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2016-11-26: With regard to SMP, the major issue is cache coherency. I added
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some special build logic to move spinlock data into the separate, non-
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cached section. That gives an improvement in performance but there are
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still hangs. These, I have determined, are to other kinds of cache
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coherency problems. Semaphores, message queues, etc. basically all
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shared data must be made coherent.
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I also added some SCU controls that should enable cache consistency for SMP
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CPUs, but I don't think I have that working right yet. See the SMP section
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below for more information.
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Platform Features
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=================
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Processor:
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- i.MX 6Quad or 6DualLite 1 GHz ARM Cortex-A9 processor
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Memory/storage:
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- 1 GB DDR3 SDRAM up to 533 MHz (1066 MTPS) memory
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- 8 GB eMMC flash
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- 4 MB SPI NOR flash
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Display:
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- 10.1" 1024 x 768 LVDS display with integrated P-cap sensing
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- HDMI connector
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- LVDS connector (for optional second display)
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- LCD expansion connector (parallel, 24-bit)
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- EPDC expansion connector (for 6DualLite only)
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- MIPI DSI connector (two data lanes, 1 GHz each)
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User Interface:
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- 10.1" capacitive multitouch display
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- Buttons: power, reset, volume
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Power Management:
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- Proprietary PF0100 PMIC
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Audio:
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- Audio codec
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- 2x digital microphones
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- 2x 3.5 mm audio ports
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- Dual 1 watt speakers
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Expansion Connector:
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- Camera MIPI CSI port
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- I2C, SPI signals
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Connectivity:
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- 2x full-size SD/MMC card slots
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- 7-pin SATA data connector
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- 10/100/1000 Ethernet port
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- 1x USB 2.0 OTG port (micro USB)
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Debug:
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- JTAG connector (20-pin)
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- 1x Serial-to-USB connector (for JTAG)
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OS Support:
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- Linux<75> and Android<69> from NXP/Freescale
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- Others supported via third party (QNX, Windows Embedded)
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Tools Support:
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- Manufacturing tool from NXP/Freescale
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- IOMUX tool from NXP/Freescale
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- Lauterbach, ARM (DS-5), IAR and Macraigor
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Additional Features:
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- Proprietary 3-axis accelerometer
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- Proprietary 3D magnetometer
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- Ambient light sensor
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- GPS receiver module
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- 2x 5MP cameras
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- Battery charger
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- Battery connectors (battery not included)
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Serial Console
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==============
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A DEBUG VCOM is available MICRO USB AB 5 J509. This corresponds to UART1
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from the i.MX6. UART1 connects to J509 via the CSIO_DAT10 and CSIO_DAT11
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pins
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LEDs and Buttons
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================
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LEDs
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----
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A single LED is available driven GPIO1_IO02. On the schematic this is
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USR_DEF_RED_LED signal to pin T1 (GPIO_2). This signal is shared with
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KEY_ROW6 (ALT2). A high value illuminates the LED.
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This LED is 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/sam_autoleds.c. The LED is used to encode
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OS-related events as follows:
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------------------- ----------------------- ------
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SYMBOL Meaning LED
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------------------- ----------------------- ------
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LED_STARTED NuttX has been started OFF
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LED_HEAPALLOCATE Heap has been allocated OFF
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LED_IRQSENABLED Interrupts enabled OFF
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LED_STACKCREATED Idle stack created ON
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LED_INIRQ In an interrupt N/C
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LED_SIGNAL In a signal handler N/C
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LED_ASSERTION An assertion failed N/C
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LED_PANIC The system has crashed FLASH
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Thus if the LED is statically on, NuttX has successfully booted and is,
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apparently, running normally. If the LED is flashing at approximately
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2Hz, then a fatal error has been detected and the system has halted.
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Buttons
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-------
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Using U-Boot to Run NuttX
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=========================
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The MCIMX6Q-SDB comes with a 8GB SD card containing the U-Boot and Android.
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You simply put the SD card in the SD card slot SD3 (on the bottom of the
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board next to the HDMI connect) and Android will boot.
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But we need some other way to boot NuttX. Here are some things that I have
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experimented with.
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Building U-Boot (Failed Attempt #1)
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-----------------------------------
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I have been unsuccessful getting building a working version of u-boot from
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scratch. It builds, but it does not run. Here are the things I did:
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1. Get a copy of the u-boot i.MX6 code via:
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https://github.com/boundarydevices/u-boot-imx6/tree/production
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or
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$ git clone git://git.denx.de/u-boot.git
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2. Build U-Boot for the i.MX6Q Sabre using the following steps. This
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assumes that you have the path to your arm-none-eabi- toolchain at the
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beginning of your PATH variable:
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$ cd u-boot
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$ export ARCH=arm
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$ export CROSS_COMPILE=arm-none-eabi-
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$ make mx6qsabresd_config
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$ make
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This should create a number of files, including u-boot.imx
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3. Format an SD card
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Create a FAT16 partition at an offset of about 1MB into the SD card.
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This is where we will put nuttx.bin.
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4. Put U-Boot on SD. U-boot should reside at offset 1024B of your SD
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card. To put it there, do:
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$ dd if=u-boot.imx of=/dev/<your-sd-card> bs=1k seek=1
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$ sync
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Your SD card device is typically something in /dev/sd<X> or
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/dev/mmcblk<X>. Note that you need write permissions on the SD card
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for the command to succeed, so you might need to su - as root, or use
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sudo, or do a chmod a+w as root on the SD card device node to grant
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permissions to users.
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Using the Other SD Card Slot (Failed Attempt #2)
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------------------------------------------------
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Another option is to use the version u-boot that came on the 8GB but put
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NuttX on another SD card inserted in the other SD card slot at the opposite
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corner of the board.
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To make a long story short: This doesn't work. As far as I can tell,
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U-Boot does not support any other other SC card except for mmc 2 with is the
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boot SD card slot.
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Replace Boot SD Card (Successful Attempt #3)
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--------------------------------------------
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What if you remove the SD card after U-boot has booted, then then insert
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another SD card containing the nuttx.bin image?
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1. Build nuttx.bin and copy it only a FAT formated SD card. Insert the SD
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card containing NuttX into the "other" SD card slot. Insert the 8GB SD
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card with U-boot already on it in the normal, boot SD card slot.
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2. Connect the VCOM port using the USB port next to the boot SD card slot.
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3. Start a console at 11500 8N1 on the VCOM port
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4. Power up the board with the 8GB SD card in place. U-Boot will start and
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countdown before starting Linux. Press enter to break into U-Boot before
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Linux is started.
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5. Remove the 8GB U-Boot SD card; insert in its place.
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6. Rescan the SD card:
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MX6Q SABRESD U-Boot > mmc dev 2
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mmc2 is current device
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MX6Q SABRESD U-Boot > mmc rescan
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MX6Q SABRESD U-Boot > fatls mmc 2
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system volume information/
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87260 nuttx.bin
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1 file(s), 1 dir(s)
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7. Then we can boot NuttX off the rescanned SD card:
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MX6Q SABRESD U-Boot > fatload mmc 2 0x10800000 nuttx.bin
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reading nuttx.bin
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87260 bytes read
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MX6Q SABRESD U-Boot > go 0x10800040
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## Starting application at 0x10800040 ...
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That seems to work okay.
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Use the FAT Partition on the 8GB SD Card (Untested Idea #4)
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-----------------------------------------------------------
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Partition 4 on the SD card is an Android FAT file system. So one thing you
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could do would be put the nuttx.bin file on that partition, then boot like:
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MX6Q SABRESD U-Boot > fatload mmc 2:4 0x10800000 nuttx.bin
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SD Card Image Copy (Successful Attempt #5)
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-------------------------------------
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You can use the 'dd' command to copy the first couple of megabytes from the
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8GB SD card and copy that to another SD card. You then have to use 'fdisk'
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to fix the partition table and to add a single FAT16 partition at an offset
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of 1MB or so.
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1. Insert the 8GB boot SD card into your PC: Copy the first 2Mb from the SD
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card to a file:
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$ dd if=/dev/sdh of=sdh.img bs=512 count=4096
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2. Remove the 8GB boot SD card and replace it with a fresh SD card. Copy the
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saved file to the first the new SD card:
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$ dd of=/dev/sdh if=sdh.img bs=512 count=4096
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3. Then use 'fdisk' to:
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- Remove all of the non-existent partitions created by the 'dd' copy.
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- Make a single FAT16 partition at the end of the SD card.
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You will also need to format the partion for FAT.
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4. You can put nuttx.bin here and then boot very simply with:
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MX6Q SABRESD U-Boot > fatload mmc 2:1 0x10800000 nuttx.bin
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MX6Q SABRESD U-Boot > go 0x10800040
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A little hokey, but not such a bad solution.
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Debugging with the Segger J-Link
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================================
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These procedures work for debugging the boot-up sequence when there is a
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single CPU running and not much else going on. If you want to do higher
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level debugger, you will need something more capable. NXP/Freescale suggest
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some other debuggers that you might want to consider.
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These instructions all assume that you have built NuttX with debug symbols
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enabled. When debugging the nuttx.bin file on the SD card, it is also
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assumed the the nuttx ELF file with the debug symbol addresses is from the
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same build so that the symbols match up.
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Debugging the NuttX image on the SD card
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----------------------------------------
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1. Connect the J-Link to the 20-pin JTAG connector.
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2. Connect the "USB TO UART" USB VCOM port to the host PC. Start a
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terminal emulation program like TeraTerm on Minicom. Select the USB
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VCOM serial port at 115200 8N1.
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When you apply power to the board, you should see the U-Boot messages in
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the terminal window. Stop the U-Boot countdown to get to the U-Boot
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prompt.
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2. Start the Segger GDB server:
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Target: MCIMX6Q6
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Target Interface: JTAG
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If the GDB server starts correctly you should see the following in the
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Log output:
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Waiting for GDB Connection
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3. In another Xterm terminal window, start arm-none-eabi-gdb and connect to
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the GDB server.
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From the Xterm Window:
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$ arm-none-eabi-gdb
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You will need to have the path to the arm-none-eabi-gdb program in your
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PATH variable.
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Then from GDB:
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gdb> target connect localhost:2331
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gdb> mon halt
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4. Start U-boot under GDB control:
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From GDB:
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gdb> mon reset
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gdb> mon go
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Again stop the U-Boot countdown to get to the U-Boot prompt.
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5. Load NuttX from the SD card into RAM
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From U-Boot:
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MX6Q SABRESD U-Boot > fatload mmc 2:1 0x10800000 nuttx.bin
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6. Load symbols and set a breakpoint
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From GDB:
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gdb> mon halt
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gdb> file nuttx
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gdb> b __start
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gdb> c
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__start is the entry point into the NuttX binary at 0x10800040. You can,
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of course, use a different symbol if you want to start debugging later
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in the boot sequence.
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7. Start NuttX
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From U-Boot:
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MX6Q SABRESD U-Boot > go 0x10800040
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8. You should hit the breakpoint that you set above and be off and
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debugging.
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Debugging a Different NuttX Image
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---------------------------------
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Q: What if I want do run a different version of nuttx than the nuttx.bin
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file on the SD card. I just want to build and debug without futzing with
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the SD card. Can I do that?
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A: Yes with the following modifications to the prodecure above.
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- Skip step 5, don't bother to load NuttX into RAM
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- In step 6, load NuttX into RAM like this:
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gdb> mon halt
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gdb> load nuttx <-- Loads NuttX into RAM at 0x010800000
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gdb> file nuttx
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gdb> b __start
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gdb> c
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- Then after step 7, you should hit the breakpoint at the instruction you
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just loaded at address 0x10800040.
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- Or, in step 6, instead of continuing ('c') which will resume U-Boot,
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even just:
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gdb> mon halt
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gdb> load nuttx <-- Loads NuttX into RAM at 0x010800000
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gdb> file nuttx
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gdb> mon set pc 0x10800040
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gdb> s
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The final single will then step into the freshly loaded program.
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You can then forget about steps 7 and 8.
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This is, in fact, my preferred way to debug.
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You can restart the debug session at any time at the gdb> prompt by:
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gdb> mon reset
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gdb> mon go
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That will restart U-Boot and you have to press ENTER in the terminal
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window to stop U-Boot. Restarting U-Boot is a necesary part of the
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restart process because you need to put the hardware back in its initial
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state before running NuttX
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Then this will restart the debug session just as before:
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gdb> mon halt
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gdb> load nuttx <-- Loads NuttX into RAM at 0x010800000
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gdb> file nuttx
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gdb> mon set pc 0x10800040
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gdb> s
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SMP
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===
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The i.MX6 6Quad has 4 CPUs. Support is included for testing an SMP
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configuration. That configuration is still not yet ready for usage but can
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be enabled with the following configuration settings:
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RTOS Features -> Tasks and Scheduling
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CONFIG_SPINLOCK=y
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CONFIG_SMP=y
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CONFIG_SMP_NCPUS=4
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CONFIG_SMP_IDLETHREAD_STACKSIZE=2048
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Open Issues:
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1. Currently all device interrupts are handled on CPU0 only. Critical sections will
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attempt to disable interrupts but will now disable interrupts only on the current
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CPU (which may not be CPU0). There is a spinlock to prohibit entrance into these
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critical sections in interrupt handlers of other CPUs.
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When the critical section is used to lock a resource that is also used by
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interupt handling, the interrupt handling logic must also take the spinlock.
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This will cause the interrupt handlers on other CPUs to spin until
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leave_critical_section() is called. More verification is needed.
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2. Cache Concurency. Cache coherency in SMP configurations is managed by the
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||
MPCore snoop control unit (SCU). But I don't think I have the set up
|
||
correctly yet.
|
||
|
||
Currently cache inconsistencies appear to be the root cause of all current SMP
|
||
issues.
|
||
|
||
Configurations
|
||
==============
|
||
|
||
Information Common to All Configurations
|
||
----------------------------------------
|
||
Each Sabre-6Quad configuration is maintained in a sub-directory and
|
||
can be selected as follow:
|
||
|
||
cd tools
|
||
./configure.sh sabre-6quad/<subdir>
|
||
cd -
|
||
. ./setenv.sh
|
||
|
||
Before sourcing the setenv.sh file above, you should examine it and perform
|
||
edits as necessary so that TOOLCHAIN_BIN is the correct path to the directory
|
||
than holds your toolchain binaries.
|
||
|
||
And then build NuttX by simply typing the following. At the conclusion of
|
||
the make, the nuttx binary will reside in an ELF file called, simply, nuttx.
|
||
|
||
make oldconfig
|
||
make
|
||
|
||
The <subdir> that is provided above as an argument to the tools/configure.sh
|
||
must be is one of the following.
|
||
|
||
NOTES:
|
||
|
||
1. These configurations use the mconf-based configuration tool. To
|
||
change any of these configurations using that tool, you should:
|
||
|
||
a. Build and install the kconfig-mconf tool. See nuttx/README.txt
|
||
see additional README.txt files in the NuttX tools repository.
|
||
|
||
b. Execute 'make menuconfig' in nuttx/ in order to start the
|
||
reconfiguration process.
|
||
|
||
2. Unless stated otherwise, all configurations generate console
|
||
output on UART1 which is a available to the host PC from the USB
|
||
micro AB as a VCOM part.
|
||
|
||
3. All of these configurations are set up to build under Windows using the
|
||
"GNU Tools for ARM Embedded Processors" that is maintained by ARM
|
||
(unless stated otherwise in the description of the configuration).
|
||
|
||
https://launchpad.net/gcc-arm-embedded
|
||
|
||
That toolchain selection can easily be reconfigured using
|
||
'make menuconfig'. Here are the relevant current settings:
|
||
|
||
Build Setup:
|
||
CONFIG_HOST_WINDOWS=y : Window environment
|
||
CONFIG_WINDOWS_CYGWIN=y : Cywin under Windows
|
||
|
||
System Type -> Toolchain:
|
||
CONFIG_ARMV7M_TOOLCHAIN_GNU_EABIW=y : GNU ARM EABI toolchain
|
||
|
||
Configuration sub-directories
|
||
-----------------------------
|
||
|
||
nsh
|
||
---
|
||
This is a NuttShell (NSH) configuration that uses the NSH library
|
||
at apps/nshlib with the start logic at apps/examples/nsh.
|
||
|
||
NOTES:
|
||
|
||
1. This configuration assumes that we are loaded into SDRAM and
|
||
started via U-Boot.
|
||
|
||
2. The serial console is configured by default for use UART1, the
|
||
USB VCOM port (UART1), same as the serial port used by U-Boot.
|
||
You will need to reconfigure if you want to use a different UART.
|
||
|
||
3. NSH built-in applications are supported, but no built-in
|
||
applications are enabled.
|
||
|
||
Binary Formats:
|
||
CONFIG_BUILTIN=y : Enable support for built-in programs
|
||
|
||
Application Configuration:
|
||
CONFIG_NSH_BUILTIN_APPS=y : Enable starting apps from NSH command line
|
||
|
||
4. The RAMLOG is enabled. All SYSLOG (DEBUG) output will go to the
|
||
RAMLOG and will not be visible unless you use the nsh 'dmesg'
|
||
command. To disable this RAMLOG feature, disable the following:
|
||
|
||
Device Drivers: CONFIG_RAMLOG
|
||
|
||
smp
|
||
---
|
||
This is a configuration of testing the SMP configuration. It is
|
||
essentially equivalent to the SMP configuration except has SMP enabled.
|
||
|
||
NOTES:
|
||
|
||
1. See the notest for the nsh configuration. Since this configuration
|
||
is essentially the same all of those comments apply.
|
||
|
||
2. SMP is not fully functional. See the STATUS and SMP sections above
|
||
for detailed SMP-related issues.
|