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-rw-r--r--user/bsps/aarch64/raspberrypi4.rst109
-rw-r--r--user/bsps/aarch64/xilinx-zynqmp.rst66
-rw-r--r--user/bsps/arm/altera-cyclone-v.rst4
-rw-r--r--user/bsps/arm/beagle.rst13
-rw-r--r--user/bsps/arm/fvp.rst39
-rw-r--r--user/bsps/arm/imx.rst25
-rw-r--r--user/bsps/arm/imxrt.rst172
-rw-r--r--user/bsps/arm/lpc24xx.rst2
-rw-r--r--user/bsps/arm/raspberrypi.rst24
-rw-r--r--user/bsps/arm/realview-pbx-a9.rst2
-rw-r--r--user/bsps/arm/stm32h7.rst546
-rw-r--r--user/bsps/arm/xen.rst4
-rw-r--r--user/bsps/arm/xilinx-zynq.rst18
-rw-r--r--user/bsps/arm/xilinx-zynqmp-rpu.rst76
-rw-r--r--user/bsps/arm/xilinx-zynqmp.rst2
-rw-r--r--user/bsps/bsps-aarch64.rst3
-rw-r--r--user/bsps/bsps-arm.rst50
-rw-r--r--user/bsps/bsps-bfin.rst2
-rw-r--r--user/bsps/bsps-i386.rst2
-rw-r--r--user/bsps/bsps-lm32.rst2
-rw-r--r--user/bsps/bsps-m68k.rst2
-rw-r--r--user/bsps/bsps-microblaze.rst49
-rw-r--r--user/bsps/bsps-mips.rst2
-rw-r--r--user/bsps/bsps-moxie.rst2
-rw-r--r--user/bsps/bsps-nios2.rst2
-rw-r--r--user/bsps/bsps-or1k.rst2
-rw-r--r--user/bsps/bsps-powerpc.rst10
-rw-r--r--user/bsps/bsps-riscv.rst403
-rw-r--r--user/bsps/bsps-sh.rst2
-rw-r--r--user/bsps/bsps-sparc.rst76
-rw-r--r--user/bsps/bsps-sparc64.rst2
-rw-r--r--user/bsps/bsps-v850.rst2
-rw-r--r--user/bsps/bsps-x86_64.rst4
-rw-r--r--user/bsps/index.rst2
34 files changed, 1530 insertions, 191 deletions
diff --git a/user/bsps/aarch64/raspberrypi4.rst b/user/bsps/aarch64/raspberrypi4.rst
new file mode 100644
index 0000000..efb09b6
--- /dev/null
+++ b/user/bsps/aarch64/raspberrypi4.rst
@@ -0,0 +1,109 @@
+.. SPDX-License-Identifier: CC-BY-SA-4.0
+
+.. Copyright (C) 2022 Mohd Noor Aman
+
+.. _BSP_aarch64_Raspberrypi_4:
+
+Raspberry Pi 4B
+===============
+
+The 'raspberrypi4b' BSP currently supports only the LP64 ABI. ILP32 is not
+supported. Raspberry pi 4B all variants and Raspberry Pi 400 are supported. The
+default bootloader which is used by the Raspbian OS or other OS can be used to
+boot RTEMS. SMP is currently not supported.
+
+Raspberry Pi 4B has 2 types of interrupt controller, GIC-400 (GICv2) and ARM
+legacy generic controller. Both are supported. By default, raspberrypi 4B uses
+ARM legacy generic controller. Set ``enable_gic=1`` in the ``config.txt`` file
+to enable GIC.
+
+Clock Driver
+------------
+
+The clock driver uses the `ARM Generic Timer`.
+
+Console Driver
+--------------
+
+Raspberry pi 4B has 2 types of UARTs, ARM PL011 and Mini-uart. The PL011 is a
+capable, broadly 16550-compatible UART, while the mini UART has a reduced
+feature set. The console driver supports the default Qemu emulated ARM PL011
+PrimeCell UART as well as the physical ARM PL011 PrimeCell UART in the
+raspberrypi hardware. Mini-uart is not supported.
+
+Preparing to boot
+------------------
+
+Raspberry Pi uses a different mechanism to boot when compared with any ARM SoC.
+First the GPU initializes, loads the bootloader (Raspberry pi firmware) and then
+looks for the kernel img. This whole process is done by the GPU (VideoCore IV)
+till the kernel is loaded. More information can be found on the `Raspberry pi
+documentation page
+<https://www.raspberrypi.com/documentation/computers/raspberry-pi.html#boot-sequence>`_.
+By default the arm64 mode looks for the ``kernel8.img``. Any other kernel can be
+loaded by adding ``kernel=<img_name>`` to the ``config.txt`` file.
+
+The Firmware files are required in order to boot RTEMS. The latest firmware can
+be downloaded from the `Raspberry Pi Firmware Repository
+<https://github.com/raspberrypi/firmware/>`_. USB boot is supported. All the
+files (Firmwares and kernel) must be place in the FAT32 partition only. Add
+``arm_64bit=1`` in the ``config.txt`` file in order to boot the BSP in 64bit
+kernel mode.
+
+
+UART Setup
+^^^^^^^^^^
+
+Connect your serial device to the GPIO15 and GPIO14. Add the following to the
+``config.txt`` file in order to use the PL011 UART0 and thus disabling the
+default Mini-uart.
+
+.. code-block:: none
+
+ # if user wants to enable GIC, uncomment the next line
+ # enable_gic=1
+ arm_64bit=1
+ dtoverlay = disable-bt
+ enable_uart=1
+
+.. note::
+ The Raspberry Pi 4B and 400 have an additional four PL011 UARTs. They are not
+ supported.
+
+Generating kernel image
+^^^^^^^^^^^^^^^^^^^^^^^
+
+The following steps show how to run ``hello.exe`` on the BSP. Other executables
+can be processed in a similar way.
+
+To create the kernel image:
+
+.. code-block:: shell
+
+ $ aarch64-rtems@rtems-ver-major@-objcopy -Obinary hello.exe kernel8.img
+
+Copy the kernel image to the SD card.
+
+JTAG Setup
+----------
+
+The Raspberry Pi 4 doesn't have dedicated JTAG pins. Instead, you must configure
+the GPIO pins (GPIO22-GPIO27) to activate the JTAG functionality. The RPi 4
+documentation refers to this as Alt4 functions of those pins. Alt5 does exist
+too, which goes from GPIO4, 5, 6, 12 and 13. you can check this out from
+`pinout.xyz <https://pinout.xyz/pinout/jtag#>`_ or `eLinux
+<https://elinux.org/RPi_BCM2835_GPIOs>`_
+
+One more thing to note on JTAG with Raspberry pi 4B is that, by default, All the
+GPIO pins are pulled down, according to the `BCM2711 documentation
+<https://datasheets.raspberrypi.com/bcm2711/bcm2711-peripherals.pdf>`_. This
+wasn't the case in the earlier models. So in order to let the data flow freely,
+we will have to disable them.
+
+.. code-block:: none
+
+ # Disable pull downs
+ gpio=22-27=np
+
+ # Enable jtag pins (i.e. GPIO22-GPIO27)
+ enable_jtag_gpio=1
diff --git a/user/bsps/aarch64/xilinx-zynqmp.rst b/user/bsps/aarch64/xilinx-zynqmp.rst
index 78bff12..4de0115 100644
--- a/user/bsps/aarch64/xilinx-zynqmp.rst
+++ b/user/bsps/aarch64/xilinx-zynqmp.rst
@@ -6,19 +6,39 @@
.. _BSP_aarch64_qemu_xilinx_zynqmp_lp64_qemu:
.. _BSP_aarch64_qemu_xilinx_zynqmp_ilp32_zu3eg:
.. _BSP_aarch64_qemu_xilinx_zynqmp_lp64_zu3eg:
+.. _BSP_aarch64_qemu_xilinx_zynqmp_lp64_cfc400x:
Qemu Xilinx ZynqMP
==================
-This BSP supports four variants: `xilinx-zynqmp-ilp32-qemu`,
-`xilinx-zynqmp-lp64-qemu`, `xilinx-zynqmp-ilp32-zu3eg`, and
-`xilinx-zynqmp-lp64-zu3eg`. Platform-specific hardware initialization is
-performed by ARM Trusted Firmware (ATF). Other basic hardware initialization is
-performed by the BSP. These BSPs support the GICv2 interrupt controller present
-in all ZynqMP systems. The zu3eg BSPs have also been tested to be fully
-functional on zu2cg boards and should also work on any other ZynqMP chip variant
-since the Processing Subsystem (PS) does not vary among chip variants other than
-the number of CPU cores available.
+This BSP family supports the following variants:
+
+* `xilinx-zynqmp-ilp32-qemu`
+
+* `xilinx-zynqmp-lp64-qemu`
+
+* `xilinx-zynqmp-ilp32-zu3eg`
+
+* `xilinx-zynqmp-lp64-zu3eg`
+
+* `xilinx-zynqmp-lp64-cfc400x`
+
+Platform-specific hardware initialization is performed by ARM Trusted Firmware
+(ATF). Other basic hardware initialization is performed by the BSP. These BSPs
+support the GICv2 interrupt controller present in all ZynqMP systems. The zu3eg
+BSPs have also been tested to be fully functional on zu2cg boards and should
+also work on any other ZynqMP chip variant since the Processing Subsystem (PS)
+does not vary among chip variants other than the number of CPU cores available.
+
+This BSP family has been tested on the following hardware:
+
+* `Avnet UltraZed-EG SOM`
+
+* `Innoflight CFC-400X`
+
+* `Trenz TE0802`
+
+* `Xilinx ZCU102`
Boot on QEMU
------------
@@ -33,6 +53,14 @@ will drop to EL1 for execution. For quick turnaround during testing, it is
recommended to use the u-boot BOOT.bin that comes with the PetaLinux prebuilts
for the board in question.
+Some systems such as the CFC-400X may require a bitstream to be loaded into the
+FPGA portion of the chip to operate as expected. This bitstream must be loaded
+before RTEMS begins operation since accesses to programmable logic (PL) memory
+space can cause the CPU to hang if the FPGA is not initialized. This can be
+performed as part of BOOT.bin or by a bootloader such as u-boot. Loading
+bitstreams from RTEMS has not been tested on the ZynqMP platform and requires
+additional libraries from Xilinx.
+
Hardware Boot Image Generation
------------------------------
@@ -116,7 +144,7 @@ Prepare your RTEMS image to boot from u-boot with the following commands:
.. code-block:: shell
- $ aarch64-rtems6-objcopy -Obinary ticker.exe ticker.bin
+ $ aarch64-rtems@rtems-ver-major@-objcopy -Obinary ticker.exe ticker.bin
$ gzip -9 ticker.bin
$ mkimage -A arm64 -O rtems -T kernel -a 0x10000000 -e 0x10000000 -n RTEMS -d ticker.bin.gz rtems.img
@@ -179,7 +207,7 @@ This is the entire boot sequence:
## Transferring control to RTEMS (at address 10000000) ...
*** BEGIN OF TEST CLOCK TICK ***
- *** TEST VERSION: 6.0.0.f381e9bab29278e4434b1a93e70d17a7562dc64c
+ *** TEST VERSION: @rtems-version@.f381e9bab29278e4434b1a93e70d17a7562dc64c
*** TEST STATE: EXPECTED_PASS
*** TEST BUILD: RTEMS_POSIX_API RTEMS_SMP
*** TEST TOOLS: 10.3.1 20210409 (RTEMS 6, RSB ad54d1dd3cf8249d9d39deb1dd28b2f294df062d, Newlib eb03ac1)
@@ -225,7 +253,7 @@ as well as the physical ARM PL011 PrimeCell UART in the ZynqMP hardware.
SDHCI Driver
------------
-The ZynqMP bsp has an SDHCI driver which allows reading to and writing from SD
+The ZynqMP bsp has an SDHCI driver which allows writing to and reading from SD
cards. These can be tested in qemu using the "-sd" option. For example:
.. code-block:: shell
@@ -242,7 +270,19 @@ Network Configuration
When used with LibBSD, these BSP variants support networking via the four
Cadence GEM instances present on all ZynqMP hardware variants. All interfaces
are enabled by default, but only interfaces with operational MII busses will be
-recognized and usable in RTEMS. Most ZynqMP dev boards use CGEM3.
+recognized and usable in RTEMS. Most ZynqMP dev boards use RGMII with CGEM3.
+
+When used with lwIP from the rtems-lwip integration repository, these BSP
+variants support networking via CGEM0 and one of the other CGEM* instances
+simultaneously. This is a limitation of the Xilinx driver, specifically
+in code referring directly to XPAR_XEMACPS_0_BASEADDR. Attempting to use more
+than two interfaces simultaneously may cause unexpected behavior. Attempting to
+use a set of two interfaces that does not include CGEM0 may cause unexpected
+behavior.
+
+The interfaces will not come up by default under lwIP and must be configured
+manually. There are examples of this in the start_networking() implementation
+in netstart.c as used by the network tests.
Running Executables on QEMU
---------------------------
diff --git a/user/bsps/arm/altera-cyclone-v.rst b/user/bsps/arm/altera-cyclone-v.rst
index 14c026c..12e563e 100644
--- a/user/bsps/arm/altera-cyclone-v.rst
+++ b/user/bsps/arm/altera-cyclone-v.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2017, 2019 embedded brains GmbH
+.. Copyright (C) 2017, 2019 embedded brains GmbH & Co. KG
.. Copyright (C) 2017, 2019 Sebastian Huber
altera-cyclone-v (Intel Cyclone V)
@@ -27,7 +27,7 @@ image. Use the following commands:
.. code-block:: none
- arm-rtems5-objcopy -O binary app.exe app.bin
+ arm-rtems@rtems-ver-major@-objcopy -O binary app.exe app.bin
gzip -9 -f -c app.bin > app.bin.gz
mkimage -A arm -O linux -T kernel -a 0x00300000 -e 0x00300000 -n RTEMS -d app.bin.gz app.img
diff --git a/user/bsps/arm/beagle.rst b/user/bsps/arm/beagle.rst
index 696b89d..55f75c0 100644
--- a/user/bsps/arm/beagle.rst
+++ b/user/bsps/arm/beagle.rst
@@ -32,7 +32,7 @@ To boot via uboot, the ELF must be converted to a U-Boot image like below:
.. code-block:: none
- arm-rtems5-objcopy hello.exe -O binary app.bin
+ arm-rtems@rtems-ver-major@-objcopy hello.exe -O binary app.bin
gzip -9 app.bin
mkimage -A arm -O linux -T kernel -a 0x80000000 -e 0x80000000 -n RTEMS -d app.bin.gz rtems-app.img
@@ -77,7 +77,8 @@ overlay has to be provided. The overlay must add an additional attribute
For example,
-.. code-block::
+.. code-block:: none
+
/dts-v1/;
/ {
@@ -109,7 +110,7 @@ For registering with a custom path, the ``bsp_register_spi()`` can be used.
The function prototype is given below:
-.. code-block:: C
+.. code-block:: c
rtems_status_code bsp_register_spi(
const char *bus_path,
@@ -153,7 +154,7 @@ The modification is:
The resulting wiring is:
-.. code-block::
+.. code-block:: none
1 === /--=== 2
3 === | === 4
@@ -166,7 +167,7 @@ The resulting wiring is:
17 === === 18
19 === === 20
-.. figure:: ../../images/user/bbb-p2-debug-mod.jpg
+.. figure:: ../../../images/user/bbb-p2-debug-mod.jpg
:width: 50%
:align: center
:alt: BeagleBone Black JTAG Hardware Modification
@@ -198,7 +199,7 @@ Cortex M only debuggers (like the Segger J-Link Edu Mini) won't work.
If the debugger offers a gdb server (like OpenOCD or Segger J-Link) the
following gdb start script can be used:
-.. code-block::
+.. code-block:: none
define reset
echo -- Reset target and wait for U-Boot to start kernel.\n
diff --git a/user/bsps/arm/fvp.rst b/user/bsps/arm/fvp.rst
new file mode 100644
index 0000000..b938e30
--- /dev/null
+++ b/user/bsps/arm/fvp.rst
@@ -0,0 +1,39 @@
+.. SPDX-License-Identifier: CC-BY-SA-4.0
+
+.. Copyright (C) 2022 embedded brains GmbH & Co. KG
+
+fvp (Fixed Virtual Platform)
+============================
+
+The BSP for the
+`Arm Fixed Virtual Platforms <https://developer.arm.com/Tools%20and%20Software/Fixed%20Virtual%20Platforms>`_
+offers one variant. You need a license from Arm to run the simulator. The
+`fvp_cortex_r52` variant supports a simulation of the Cortex-R52 processor.
+The BSP supports the SMP configuration.
+
+Run an Executable
+-----------------
+
+To run an executable on a single Cortex-R52 processor use:
+
+.. code-block:: none
+
+ FVP_BaseR_Cortex-R52x1 -C bp.vis.disable_visualisation=1 -a build/arm/fvp_cortex_r52/testsuites/samples/ticker.exe
+
+To run an executable on a four Cortex-R52 processors use:
+
+.. code-block:: none
+
+ FVP_BaseR_Cortex-R52x4 -C bp.vis.disable_visualisation=1 -a build/arm/fvp_cortex_r52/testsuites/samples/ticker.exe
+
+Clock Driver
+------------
+
+The clock driver uses the `ARMv7-AR Generic Timer`.
+
+Console Driver
+--------------
+
+The console driver uses the
+`semihosting <https://developer.arm.com/documentation/dui0471/g/Semihosting/Semihosting-operations?lang=en>`_
+``SYS_READC`` and ``SYS_WRITEC`` system calls.
diff --git a/user/bsps/arm/imx.rst b/user/bsps/arm/imx.rst
index ee98f0b..47ad503 100644
--- a/user/bsps/arm/imx.rst
+++ b/user/bsps/arm/imx.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2017, 2019 embedded brains GmbH
+.. Copyright (C) 2017, 2019 embedded brains GmbH & Co. KG
.. Copyright (C) 2017, 2019 Sebastian Huber
imx (NXP i.MX)
@@ -15,7 +15,9 @@ U-Boot or barebox.
Build Configuration Options
---------------------------
-The following options are available at the configure command line.
+The following options can be used in the BSP section of the waf
+configuration INI file. The waf defaults can be used to inspect the
+values.
``BSP_PRESS_KEY_FOR_RESET``
If defined to a non-zero value, then print a message and wait until pressed
@@ -73,7 +75,7 @@ image. Use the following commands:
.. code-block:: none
- arm-rtems5-objcopy -O binary app.exe app.bin
+ arm-rtems@rtems-ver-major@-objcopy -O binary app.exe app.bin
gzip -9 -f -c app.bin > app.bin.gz
mkimage -A arm -O linux -T kernel -a 0x80200000 -e 0x80200000 -n RTEMS -d app.bin.gz app.img
@@ -174,6 +176,23 @@ config like that:
SYSINIT_DRIVER_REFERENCE(ksz8091rnb, miibus);
#include <machine/rtems-bsd-config.h>
+On chips with two Ethernet controllers, the MDIO lines are shared between the
+two controllers for a number of chips variants. This is currently supported with
+some restrictions on the initialization order. For this configuration to work,
+you have to make sure that the pins are assigned to the Ethernet controller that
+is initialized first. The initialization order in `libbsd` depends on the order
+of the Ethernet controllers in the device tree. So if (for example) `fec2` is
+defined in the device tree sources before `fec1`, make sure that the MDIO lines
+are routed to `fec2` and that the Ethernet PHYs are a sub-node of `fec2` in the
+device tree.
+
+Note that the clock for the second Ethernet controller is not necessarily
+enabled in the `CCM`. On the i.MX6UL/ULL, the clock will be enabled by the
+startup code if the node that is compatible with `fsl,imx6ul-anatop` can be
+found in the device tree. If you have trouble with the second Ethernet
+controller make sure that the `ENET2_125M_EN` bit in the `CCM_ANALOG_PLL_ENET`
+register is set as expected.
+
MMC/SDCard Driver
-----------------
diff --git a/user/bsps/arm/imxrt.rst b/user/bsps/arm/imxrt.rst
index 6dacfd9..30b1437 100644
--- a/user/bsps/arm/imxrt.rst
+++ b/user/bsps/arm/imxrt.rst
@@ -1,29 +1,48 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2020 embedded brains GmbH
+.. Copyright (C) 2020 embedded brains GmbH & Co. KG
.. Copyright (C) 2020 Christian Mauderer
imxrt (NXP i.MXRT)
==================
-This BSP offers only one variant, the `imxrt1052`. This variant supports the
-i.MXRT 1052 processor on a IMXRT1050-EVKB (tested with rev A1). You can also
-configure it to work with custom boards.
+This BSP offers multiple variants. The `imxrt1052` supports the i.MXRT 1052
+processor on a IMXRT1050-EVKB (tested with rev A1). Some possibilities to adapt
+it to a custom board are described below.
NOTE: The IMXRT1050-EVKB has an backlight controller that must not be enabled
without load. Make sure to either attach a load, disable it by software or
disable it by removing the 0-Ohm resistor on it's input.
+The `imxrt1166-cm7-saltshaker` supports an application specific board. Adapting
+it to another i.MXRT1166 based board works similar like for the `imxrt1052` BSP.
+
Build Configuration Options
---------------------------
Please see the documentation of the `IMXRT_*` and `BSP_*` configuration options
for that. You can generate a default set of options with::
- ./waf bsp_defaults --rtems-bsps=arm/imxrt1052 > config.ini
+ ./waf bspdefaults --rtems-bsps=arm/imxrt1052 > config.ini
-Boot Process
-------------
+Adapting to a different board
+-----------------------------
+
+This is only a short overview for the most important steps to adapt the BSP to
+another board. Details for most steps follow further below.
+
+#. The device tree has to be adapted to fit the target hardware.
+#. A matching clock configuration is necessary (simplest method is to generate
+ it with the NXP PinMux tool)
+#. The `dcd_data` has to be adapted. That is used for example to initialize
+ SDRAM.
+#. `imxrt_flexspi_config` has to be adapted to match the Flash connected to
+ FlexSPI (if that is used).
+#. `BOARD_InitDEBUG_UARTPins` should be adapted to match the used system
+ console.
+
+Boot Process of IMXRT1050-EVKB
+------------------------------
There are two possible boot processes supported:
@@ -39,7 +58,7 @@ For programming the HyperFlash in case 1, you can use the on board debugger
integrated into the IMXRT1050-EVKB. You can generate a flash image out of a
compiled RTEMS application with for example::
- arm-rtems6-objcopy -O binary build/arm/imxrt1052/testsuites/samples/hello.exe hello.bin
+ arm-rtems@rtems-ver-major@-objcopy -O binary build/arm/imxrt1052/testsuites/samples/hello.exe hello.bin
Then just copy the generated binary to the mass storage provided by the
debugger. Wait a bit till the mass storage vanishes and re-appears. After that,
@@ -82,34 +101,36 @@ ones that need different values):
You can find the default definitions in `bsps/arm/imxrt/start/flash-*.c`. Take a
look at the `i.MX RT1050 Processor Reference Manual, Rev. 4, 12/2019` chapter
-`9.7 Program image` for details about the contents.
+`9.7 Program image` or `i.MX RT1166 Processor Reference Manual, Rev. 0, 05/2021`
+chapter `10.7 Program image` for details about the contents.
FDT
---
The BSP uses a FDT based initialization. The FDT is linked into the application.
-You can find the default FDT used in the BSP in
-`bsps/arm/imxrt/dts/imxrt1050-evkb.dts`. The FDT is split up into two parts. The
-core part is put into an `dtsi` file and is installed together with normal
-headers into `${PREFIX}/arm-rtems6/imxrt1052/lib/include`. You can use that to
+You can find the default FDT used in the BSPs in `bsps/arm/imxrt/dts`. The FDT
+is split up into two parts. The controller specific part is put into an `dtsi`
+file. The board specific one is in the dts file. Both are installed together
+with normal headers into
+`${PREFIX}/arm-rtems@rtems-ver-major@/${BSP}/lib/include`. You can use that to
create your own device tree based on that. Basically use something like::
/dts-v1/;
-
+
#include <imxrt/imxrt1050-pinfunc.h>
#include <imxrt/imxrt1050.dtsi>
-
+
&lpuart1 {
pinctrl-0 = <&pinctrl_lpuart1>;
status = "okay";
};
-
+
&chosen {
stdout-path = &lpuart1;
};
-
+
/* put your further devices here */
-
+
&iomuxc {
pinctrl_lpuart1: lpuart1grp {
fsl,pins = <
@@ -117,43 +138,25 @@ create your own device tree based on that. Basically use something like::
IMXRT_PAD_GPIO_AD_B0_13__LPUART1_RX 0x13000
>;
};
-
+
/* put your further pinctrl groups here */
};
You can then convert your FDT into a C file with (replace `YOUR.dts` and similar
-with your FDT source names)::
+with your FDT source names):
+
+.. code-block:: none
- sh> arm-rtems6-cpp -P -x assembler-with-cpp \
- -I ${PREFIX}/arm-rtems6/imxrt1052/lib/include \
- -include "YOUR.dts" /dev/null | \
- dtc -O dtb -o "YOUR.dtb" -b 0 -p 64
+ sh> arm-rtems@rtems-ver-major@-cpp -P -x assembler-with-cpp \
+ -I ${PREFIX}/arm-rtems@rtems-ver-major@/imxrt1052/lib/include \
+ -include "YOUR.dts" /dev/null | \
+ dtc -O dtb -o "YOUR.dtb" -b 0 -p 64
sh> rtems-bin2c -A 8 -C -N imxrt_dtb "YOUR.dtb" "YOUR.c"
You'll get a C file which defines the `imxrt_dtb` array. Make sure that your new
C file is compiled and linked into the application. It will overwrite the
existing definition of the `imxrt_dtb` in RTEMS.
-PLL Settings
-------------
-
-The commercial variant of the i.MXRT1052 on the evaluation board allows a clock
-up to 600MHz for the ARM core. For some industrial variants only up to 528MHz
-are specified. To make it possible to adapt to these variants the application
-can overwrite the following constant:
-
-.. code-block:: c
-
- #include "fsl_clock_config.h"
-
- const clock_arm_pll_config_t armPllConfig_BOARD_BootClockRUN = {
- .loopDivider = 100,
- .src = 0,
- };
-
-With the default configuration of a 24MHz oscillator, the loopDivider has to be
-88 for the 528MHz.
-
Clock Driver
------------
@@ -195,10 +198,38 @@ Note that the SPI-pins on the evaluation board are shared with the SD card.
Populate R278, R279, R280, R281 on the IMXRT1050-EVKB (Rev A) to use the SPI
pins on the Arduino connector.
+By default, the native chip selects are used. If you want to use GPIOs as chip
+select instead, you can use the `cs-gpios` and `num-cs` attributes just like on
+a Linux SPI controller. A maximum of `IMXRT_LPSPI_MAX_CS` pins can be used.
+
+The hardware doesn't support selecting no native chip select during a transfer.
+Therefore one native chip select has to be reserved as a dummy if you want to be
+able to use GPIOs. The pin function for this chip select must not be configured
+on any pin. Dummy will be the first of the first four chip selects that is not a
+native one. Example configuration::
+
+ &lpspi4 {
+ status = "okay";
+ pinctrl-0 = <&my_pinctrl_lpspi4>;
+ cs-gpios = <0>, <0>, <&gpio1 1 0>, <0>, <&gpio11 5 1>;
+ num-cs = <5>;
+ }
+
+In this case, CS2 will be the dummy chip select and no pin must be configured
+with that function. CS0, CS1 and CS3 are just native chip selects and should be
+used via pin functions. GPIO1.1 is used as a high active CS and GPIO11.5 a low
+active one.
+
Limitations:
* Only a basic SPI driver is implemented. This is mostly a driver limitation and
not a hardware one.
+* GPIO CS pins on i.MXRT10xx are not tested. The chip has a lot of errate so
+ they might not work.
+* Switching from one mode (CPOL/CPHA) to another one can lead to single wrong
+ edges on the CLK line if GPIO CS pins are involved. Make sure to stuff a dummy
+ transfer with `SPI_NO_CS` set if you use multiple modes together with a GPIO
+ CS.
Network Interface Driver
------------------------
@@ -222,13 +253,58 @@ the SDK. But please note that they are not tested and maybe won't work out of
the box. Everything that works with interrupts most likely needs some special
treatment.
-Caveats
--------
+The SDK files are imported to RTEMS from the NXP mcux-sdk git repository that
+you can find here: https://github.com/nxp-mcuxpresso/mcux-sdk/
+
+The directory structure has been preserved and all files are in a
+`bsps/arm/imxrt/mcux-sdk` directory. All patches to the files are marked with
+`#ifdef __rtems__` markers.
+
+The suggested method to import new or updated files is to apply all RTEMS
+patches to the mcux-sdk repository, rebase them to the latest mcux-sdk release
+and re-import the files. The new base revision should be mentioned in the commit
+description to make future updates simpler.
+
+A import helper script (that might or might not work on newer releases of the
+mcux-sdk) can be found here:
+https://raw.githubusercontent.com/c-mauderer/nxp-mcux-sdk/d21c3e61eb8602b2cf8f45fed0afa50c6aee932f/export_to_RTEMS.py
+
+Clocks and SDRAM
+----------------
The clock configuration support is quite rudimentary. The same is true for
SDRAM. It mostly relies on the DCD and on a static clock configuration that is
taken from the NXP SDK example projects.
-The MPU settings are currently quite permissive.
+If you need to adapt the DCD or clock config to support a different hardware,
+you should generate these files using the NXP MCUXpresso Configuration Tools.
+You can add the generated files to your application to overwrite the default
+RTEMS ones or you can add them to RTEMS in a new BSP variant.
+
+As a special case, the imxrt1052 BSP will adapt it's PLL setting based on the
+chip variant. The commercial variant of the i.MXRT1052 will use a core clock of
+600MHz for the ARM core. The industrial variants only uses 528MHz. For other
+chip or BSP variants, you should adapt the files generated with the MCUXpresso
+Configuration Tools.
+
+Caveats
+-------
+
+* The MPU settings are currently quite permissive.
+
+* There is no power management support.
+
+* On the i.MXRT1166, sleeping of the Cortex M7 can't be disabled even for
+ debugging purposes. That makes it hard for a debugger to access the
+ controller. To make debugging a bit easier, it's possible to overwrite the
+ idle thread with the following one in the application:
+
+ .. code-block:: c
-There is no power management support.
+ void * _CPU_Thread_Idle_body(uintptr_t ignored)
+ {
+ (void)ignored;
+ while (true) {
+ /* void */
+ }
+ }
diff --git a/user/bsps/arm/lpc24xx.rst b/user/bsps/arm/lpc24xx.rst
index ecf1d84..f287dc8 100644
--- a/user/bsps/arm/lpc24xx.rst
+++ b/user/bsps/arm/lpc24xx.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2017, 2019 embedded brains GmbH
+.. Copyright (C) 2017, 2019 embedded brains GmbH & Co. KG
.. Copyright (C) 2017, 2019 Sebastian Huber
lpc24xx (NXP LPC17XX/LPC24XX/LPC40XX)
diff --git a/user/bsps/arm/raspberrypi.rst b/user/bsps/arm/raspberrypi.rst
index 235134f..8f40e92 100644
--- a/user/bsps/arm/raspberrypi.rst
+++ b/user/bsps/arm/raspberrypi.rst
@@ -12,7 +12,7 @@ The default bootloader on the Raspberry Pi which is used to boot Raspbian
or other OS can be also used to boot RTEMS. U-boot can also be used.
Setup SD card
-----------------
+-------------
The Raspberry Pis have an unconventional booting mechanism. The GPU
boots first, initializes itself, runs the bootloader and starts the CPU.
@@ -20,13 +20,13 @@ The bootloader looks for a kernel image, by default the kernel images must
have a name of the form ``kernel*.img`` but this can be changed by adding
`kernel=<img_name>` to ``config.txt``.
-You must provide the required firmware files on the SD card for the GPU to proceed,
-and thereby to boot RTEMS.
-The BSP currently boots up with an older version of the official firmware. These files
-can be downloaded from
-`the Raspberry Pi Firmware Repository <https://github.com/raspberrypi/firmware/tree/1.20200601/boot>`_.
-You can remove the ``kernel*.img`` files if you want to, but don't touch
-the other files.
+You must provide the required firmware files on the SD card for the GPU to
+proceed, and thereby to boot RTEMS. The BSP currently boots up with an older
+version of the official firmware. These files can be downloaded from `the
+Raspberry Pi Firmware Repository
+<https://github.com/raspberrypi/firmware/tree/1.20200601/boot>`_. You can
+remove the ``kernel*.img`` files if you want to, but don't touch the other
+files.
Copy these files in to a SD card with FAT filesystem.
@@ -41,7 +41,7 @@ To create the kernel image:
.. code-block:: none
- $ arm-rtems5-objcopy -Obinary hello.exe kernel.img
+ $ xsarm-rtems@rtems-ver-major@-objcopy -Obinary hello.exe kernel.img
Copy the kernel image to the SD card.
@@ -54,7 +54,7 @@ Make sure you have these lines below, in your ``config.txt``.
kernel=kernel.img
SPI Driver
-------------
+----------
SPI drivers are registered by the ``rpi_spi_init(bool bidirectional_mode)`` function.
@@ -72,7 +72,7 @@ SPI drivers are registered by the ``rpi_spi_init(bool bidirectional_mode)`` func
}
I2C Driver
-------------
+----------
I2C drivers are registered by the ``rpi_setup_i2c_bus()`` function.
@@ -132,7 +132,7 @@ In a new terminal, run GDB using
.. code-block:: none
- $ arm-rtems5-gdb hello.exe
+ $ arm-rtems@rtems-ver-major@-gdb hello.exe
This will open GDB and will load the symbol table from hello.exe. Issue the
following commands in the GDB prompt.
diff --git a/user/bsps/arm/realview-pbx-a9.rst b/user/bsps/arm/realview-pbx-a9.rst
index 15d1fbf..bbe0269 100644
--- a/user/bsps/arm/realview-pbx-a9.rst
+++ b/user/bsps/arm/realview-pbx-a9.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2020 embedded brains GmbH (http://www.embedded-brains.de)
+.. Copyright (C) 2020 embedded brains GmbH & Co. KG
realview-pbx-a9
===============
diff --git a/user/bsps/arm/stm32h7.rst b/user/bsps/arm/stm32h7.rst
index b508595..cdf4d43 100644
--- a/user/bsps/arm/stm32h7.rst
+++ b/user/bsps/arm/stm32h7.rst
@@ -1,6 +1,8 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2020 embedded brains GmbH
+.. Copyright (C) 2020 embedded brains GmbH & Co. KG
+
+.. Copyright (C) 2022 Karel Gardas <karel@functional.vision>
stm32h7
=======
@@ -8,10 +10,28 @@ stm32h7
This BSP supports the
`STM32H7 Series <https://www.st.com/en/microcontrollers-microprocessors/stm32h7-series.html>`_.
-The BSP is known to run on these boards:
+The BSP is known to run on these boards on specified core with using specified BSP variant.
+
+.. table::
+
+ +----------------------------------------------------------------------------------+-----------+------------------------+
+ | Board name | Core name | BSP variant name |
+ +==================================================================================+===========+========================+
+ |`STM32H743I-EVAL 2 <https://www.st.com/en/evaluation-tools/stm32h743i-eval.html>`_| M7 | arm/stm32h7 |
+ +----------------------------------------------------------------------------------+-----------+------------------------+
+ |`STM32H743ZI-Nucleo <https://www.st.com/en/evaluation-tools/nucleo-h743zi.html>`_ | M7 | arm/nucleo-h743zi |
+ +----------------------------------------------------------------------------------+-----------+------------------------+
+ |`STM32H7B3I-DK <https://www.st.com/en/evaluation-tools/stm32h7b3i-dk.html>`_ | M7 | arm/stm32h7b3i-dk |
+ +----------------------------------------------------------------------------------+-----------+------------------------+
+ |`STM32H757I-EVAL <https://www.st.com/en/evaluation-tools/stm32h757i-eval.html>`_ | M7 | arm/stm32h757i-eval |
+ | +-----------+------------------------+
+ | | M4 | arm/stm32h757i-eval-m4 |
+ +----------------------------------------------------------------------------------+-----------+------------------------+
+ |`STM32H747I-DISCO <https://www.st.com/en/evaluation-tools/stm32h747i-disco.html>`_| M7 | arm/stm32h747i-disco |
+ | +-----------+------------------------+
+ | | M4 | arm/stm32h747i-disco-m4|
+ +----------------------------------------------------------------------------------+-----------+------------------------+
-* `STM32H743I-EVAL 2 <https://www.st.com/en/evaluation-tools/stm32h743i-eval.html>`_
-* `STM32H743ZI-Nucleo <https://www.st.com/en/evaluation-tools/nucleo-h743zi.html>`_
Clock Driver
------------
@@ -23,20 +43,28 @@ boards, so it is recommended to check the default values of the BSP.
Console Driver
--------------
-The console driver supports the on-chip UART and USART modules.
-Different board variations use different GPIO pins and blocks for the default
-communication UART and it is recommended to check whether the default
-configuration provided is valid in the BSP.
+The console driver supports the on-chip UART and USART modules. Even
+the MCU supports about 10 U(S)ARTs, only those supported by the chosen
+board are enabled by default configuration. The board needs to support
+some kind of connector-based connection to the U(S)ART in order for the
+feature to be considered supported here.
+..
+.. Leaving previous notes here as a comment. They may still be useful
+.. and incorporated into the later version of the document.
+..
+.. Different board variations use different GPIO pins and blocks for the default
+.. communication UART and it is recommended to check whether the default
+.. configuration provided is valid in the BSP.
-To specify that the BSP should be built for the STM32H743ZI-Nucleo board,
-users can supply ``STM32H743ZI_NUCLEO = True`` to ``config.ini`` when
-building the BSP.
+.. To specify that the BSP should be built for the STM32H743ZI-Nucleo board,
+.. users can supply ``STM32H743ZI_NUCLEO = True`` to ``config.ini`` when
+.. building the BSP.
-Alternatively, users can supply the configuration structs defined in ``hal.h``
-in the application for other boards. For the console driver, the
-``stm32h7_usartX_config`` structs are used to configure the GPIO pins and other
-parameters. The default implementations can be found in
-``bsps/arm/stm32ht/console`` in the RTEMS sources.
+.. Alternatively, users can supply the configuration structs defined in ``hal.h``
+.. in the application for other boards. For the console driver, the
+.. ``stm32h7_usartX_config`` structs are used to configure the GPIO pins and other
+.. parameters. The default implementations can be found in
+.. ``bsps/arm/stm32ht/console`` in the RTEMS sources.
Network Interface Driver
------------------------
@@ -70,6 +98,490 @@ Known limitations:
for UHS cards are not available. All cards fall back to High Speed transfers.
* The driver uses the IDMA only. MDMA is currently not implemented. For SDMMC1
that means that the memory buffers can only come from AXI SRAM, QSPI memory,
- Flash or the FMC (SDRAM, ...). The internal SRAM1, SRAM2, SRAM3 and SRAM4 is
+ Flash or the FMC (SDRAM, ...). The internal SRAM1, SRAM2, SRAM3 and SRAM4 are
not supported. SDMMC2 should not have that limitation. See ST AN5200 "Getting
started with STM32H7 Series SDMMC host controller" for more details.
+
+
+How to run RTEMS on the board
+-----------------------------
+Following few paragraphs save a purpose of simple HOWTO or a quick
+starting guide for the users not versed in STM32 toolchain and their
+boards workflow.
+
+Board hardware setup
+^^^^^^^^^^^^^^^^^^^^
+Connect board with the host computer using micro-USB cable connected
+to micro-USB connector on the board marked with 'ST-LINK V3E' in case of evaluation
+and discovery boards or with 'USB PWR' in case of Nucleo board.
+
+STM32CubeIDE installation
+^^^^^^^^^^^^^^^^^^^^^^^^^
+Download and install STM32CubeIDE from
+https://www.st.com/en/development-tools/stm32cubeide.html. Install the
+software into the user directory. On Linux install with 'sudo' command
+to install as a root since as part of the installation USB permissions
+rules for ST-Link GDB server are also installed. The reason for
+installing into the user directory is that the IDE is based on
+Eclipse, which provides
+its own update method and this will not work well in case of read-only
+access to the installation directory. In case of any troubles consult
+installation manual provided by ST here https://www.st.com/resource/en/user_manual/um2563-stm32cubeide-installation-guide-stmicroelectronics.pdf.
+Although we will not used full fledged IDE here, the package provides ST-Link GDB Server which will be used for uploading RTEMS binaries to the board
+memory.
+
+STM32CubeProgrammer installation
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+Download and install STM32CubeProgrammer from
+https://www.st.com/en/development-tools/stm32cubeprog.html. We will
+use this software for board setup required for RTEMS and later when
+something goes wrong to delete content of the MCU flash memory. The
+software is also internally used by the ST-Link GDB Server from
+STM32CubeIDE so it is crucial to have it installed.
+
+Board ST-Link firmware upgrade
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+Download ST-Link board firmware upgrade package from
+https://www.st.com/en/development-tools/stsw-link007.html. The
+software is distributed in a form of Java jar file for Linux and Mac
+OSX and in a form of Windows binary for MS Windows. Unpack it
+somewhere and run it with
+
+.. code-block:: shell
+
+ $ unzip en.stsw-link007-v3-9-3_v3.9.3.zip
+ $ cd stsw-link007/AllPlatforms
+ $ java -jar STLinkUpgrade.jar
+
+Click on *Open in update mode* button and then if *Version* and *Update
+to Firmware* version information are different in shown version number/code, click on *Upgrade*
+button and wait till upgrade finishes.
+
+.. note: On Linux you will need to have libusb library installed in
+ order to make upgrade process working. On Ubuntu 20.04 LTS you can do
+ that with following command.
+
+.. code-block:: shell
+
+ $ sudo apt install libusb-1.0-0
+
+
+Dual core board setup for RTEMS
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+Current RTEMS BSP supports
+running MCU in a single-core mode only on either M7 core or M4
+core. That means that to not leave other core interfering with the
+system we either need to upload short infinite loop code to it or we
+may switch off the core completely. The second option is what is
+described here. The board by default switches on and starts both
+cores. Based on chosen BSP variant you may like to switch off other
+core with using STMCubeProgrammer tool.
+Go to the directory where you have installed STMCubeProgrammer
+software and run it with
+
+.. code-block:: shell
+
+ $ cd bin
+ $ ./STM32CubeProgrammer
+
+
+.. important:: It is absolutely necessary you will do that from inside the bin
+ directory where STM32CubeProgrammer binary resides. If you don't, then
+ programmer UI will crash on attempt to connect to the board. Probable
+ reason is a bug in the programmer which is not able to correctly locate
+ its C dynamic library responsible for connecting to the ST-Link board
+ interface. Version 2.9.0 of the programmer is described here. Other
+ versions may behave a bit differently.
+
+When you start the programmer application, the UI window of the programmer will
+appear.
+Click on green *Connect* button in the right upper corner of
+the UI. This will connect programmer to the board.
+Then click on *OB*
+icon in the left upper corner. Actually this is hidden menu item which you
+can un-hide by clicking on menu icon (three horizontal stripes) in the
+upper left corner.
+When you click on *OB* or *Option bytes* in un-hidden state, then
+click on *User Configuration* in the options list and when the user
+configuration list opens
+unselect preselected *BCM4* item inside it to switch off M4 core or
+unselect preselected *BCM7* item to switch off M7 core from
+starting up. The action needs to be saved by clicking on *Apply* button
+below the option table.
+
+.. warning:: Be careful! Wrong setup in STM32H7 configuration may result in
+ *bricked* board.
+
+Do not forget to disconnect the programmer application from the board by clicking on green *Disconnect* button
+in the upper right corner and then close the programmer UI.
+
+.. important:: If you keep programmer connected then you will not be able
+ to connect ST-Link GDB server to the board and upload RTEMS binary to
+ it.
+
+
+STM32CubeIDE ST-Link GDB Server setup
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+In order to use STM provided ST-Link GDB server externally, that is
+not from inside the IDE, we need to configure it. Please go to the
+directory where you have installed STM32CubeIDE software. Look for
+file containing *ST-LINK* string inside its name. Following shell
+command sequence shows example about how to find it.
+
+.. code-block:: shell
+
+ $ cd $HOME/sfw/stm32cubeide_1.8.0
+ $ find . -name 'ST-LINK*'
+ ./plugins/com.st.stm32cube.ide.mcu.externaltools.stlink-gdb-server.linux64_2.0.200.202202231230/tools/bin/ST-LINK_gdbserver.sh
+ ./plugins/com.st.stm32cube.ide.mcu.externaltools.stlink-gdb-server.linux64_2.0.200.202202231230/tools/bin/ST-LINK_gdbserver
+ ./plugins/com.st.stm32cube.ide.mcu.externaltools.stlink-gdb-server.linux64_2.0.100.202109301221/tools/bin/ST-LINK_gdbserver.sh
+ ./plugins/com.st.stm32cube.ide.mcu.externaltools.stlink-gdb-server.linux64_2.0.100.202109301221/tools/bin/ST-LINK_gdbserver
+
+Notice that in this particular installation case we already have two
+versions of GDB server installed. This is due to fact that version
+1.8.0 of the IDE was later upgraded to 1.9.0 version. Anyway, we will choose
+to use the latest one, or if there is only one, then the only one
+installed. Please go to its *bin* directory. E.g.
+
+.. code-block:: shell
+
+ $ cd plugins/com.st.stm32cube.ide.mcu.externaltools.stlink-gdb-server.linux64_2.0.200.202202231230/tools/bin
+
+Now, you will need to edit provided *config.txt* file inside the
+directory. Use your favorite editor. Open the file and scroll
+down to its end. You will see following comment:
+
+.. code-block:: none
+
+ ###############################################################
+ # -cp <path> : Path to STM32CubeProgrammer
+ # Modify to correct path
+ # for STM32_Programmer_CLI executable
+ ###############################################################
+ -cp
+
+and here you will need to place path where your STM32CubeProgrammer is
+installed directly behind the *-cp* parameter. E.g.
+
+.. code-block:: none
+
+ ###############################################################
+ # -cp <path> : Path to STM32CubeProgrammer
+ # Modify to correct path
+ # for STM32_Programmer_CLI executable
+ ###############################################################
+ -cp /home/karel/sfw/stm32cubeide_1.8.0/plugins/com.st.stm32cube.ide.mcu.externaltools.cubeprogrammer.linux64_2.0.200.202202231230/tools/bin
+
+Once you are done with it, you can save the file and close the
+editor. Let's verify that GDB server is configured and running well by starting
+it inside the shell. Please go inside the directory where
+ST-LINK_gdbserver.sh is located and run it by:
+
+.. code-block:: shell
+
+ $ ./ST-LINK_gdbserver.sh
+
+If everything is all right and if you have board still connected to
+the host computer then you should see output like following:
+
+.. code-block:: shell
+
+ $ ./ST-LINK_gdbserver.sh
+
+ STMicroelectronics ST-LINK GDB server. Version 6.1.0
+ Copyright (c) 2022, STMicroelectronics. All rights reserved.
+
+ Starting server with the following options:
+ Persistent Mode : Enabled
+ LogFile Name : debug.log
+ Logging Level : 31
+ Listen Port Number : 61234
+ Status Refresh Delay : 15s
+ Verbose Mode : Disabled
+ SWD Debug : Enabled
+
+ COM frequency = 24000 kHz
+ Target connection mode: Default
+ Reading ROM table for AP 0 @0xe00fefd0
+ Hardware watchpoint supported by the target
+ ST-LINK Firmware version : V3J9M3
+ Device ID: 0x450
+ PC: 0x8028fa4
+ ST-LINK device status: HALT_MODE
+ ST-LINK detects target voltage = 3.28 V
+ ST-LINK device status: HALT_MODE
+ ST-LINK device initialization OK
+ Stm32Device, pollAndNotify running...
+ SwvSrv state change: 0 -> 1
+ Waiting for connection on port 61235...
+ Waiting for debugger connection...
+ Waiting for connection on port 61234...
+
+In output above you can see ST-Link GDB server waiting for debugger
+connection. If this is the case in your case, then you can finish GDB server by hitting
+*Ctrl-C* key combination.
+
+RTEMS BSP samples build and run
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+We will use STM32H747I-DISCO board as an example hereafter. If you use
+different board please adjust configuration steps in BSP configuration
+accordingly. You should use BSP variant name specified for your
+particular board in the table above.
+
+Generate default configuration for the board:
+
+.. code-block:: shell
+
+ $ ./waf bspdefaults --rtems-bsps=arm/stm32h747i-disco > stm32h747i-disco.ini
+ Regenerate build specification cache (needs a couple of seconds)...
+
+To run basic hello world or ticker samples you do not need to modify
+default BSP configuration here as the compilation of basic RTEMS demo samples is
+enabled by default. Let's continue with configuration of
+the RTEMS source by running following command. Please change the RTEMS
+tools installation prefix to suite your installation.
+
+.. code-block:: shell
+
+ $ ./waf configure --rtems-bsps=arm/stm32h747i-disco --rtems-config=./stm32h747i-disco.ini --rtems-tools=$HOME/workspace/rtems-tools
+ Setting top to : /home/rtems/workspace/rtems
+ Setting out to : /home/rtems/workspace/rtems/build
+ Configure board support package (BSP) : arm/stm32h747i-disco
+ Checking for program 'arm-rtems6-gcc' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-gcc
+ Checking for program 'arm-rtems6-g++' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-g++
+ Checking for program 'arm-rtems6-ar' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-ar
+ Checking for program 'arm-rtems6-ld' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-ld
+ Checking for program 'ar' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-ar
+ Checking for program 'g++, c++' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-g++
+ Checking for program 'ar' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-ar
+ Checking for program 'gas, gcc' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-gcc
+ Checking for program 'ar' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-ar
+ Checking for program 'gcc, cc' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-gcc
+ Checking for program 'ar' : /home/rtems/workspace/rtems-tools/bin/arm-rtems6-ar
+ Checking for asm flags '-MMD' : yes
+ Checking for c flags '-MMD' : yes
+ Checking for cxx flags '-MMD' : yes
+ 'configure' finished successfully (0.454s)
+
+Build the BSP including samples using *build* command:
+
+.. code-block:: shell
+
+ $ ./waf build
+
+the command outputs a lot of information about files being compiled
+and ends with output like:
+
+.. code-block:: shell
+
+ Waf: Leaving directory `/home/rtems/workspace/rtems/build/arm/stm32h747i-disco'
+ 'build_arm/stm32h747i-disco' finished successfully (12.086s)
+
+As your RTEMS BSP including samples is compiled, we will proceed with
+running the hello world sample on the board now.
+Open 3 shell windows for the test on the host computer. Also make sure
+board is connected to the computer and is running. It does not matter
+if manufacturer's demo is running there or if you navigated to some
+demo part and left it there. ST-Link GDB server always takes over the
+board when connected to it.
+
+Start GDB server in the first window by switching to GDB server
+directory and running the shell script. This is from testing machine
+installation, the path to GDB server will probably look different in your
+installation case.
+
+.. code-block:: shell
+
+ $ cd sfw/stm32cubeide_1.8.0/plugins/com.st.stm32cube.ide.mcu.externaltools.stlink-gdb-server.linux64_2.0.200.202202231230/tools/bin
+ $ ./ST-LINK_gdbserver.sh
+
+ STMicroelectronics ST-LINK GDB server. Version 6.1.0
+ Copyright (c) 2022, STMicroelectronics. All rights reserved.
+
+ Starting server with the following options:
+ Persistent Mode : Enabled
+ LogFile Name : debug.log
+ Logging Level : 31
+ Listen Port Number : 61234
+ Status Refresh Delay : 15s
+ Verbose Mode : Disabled
+ SWD Debug : Enabled
+
+ COM frequency = 24000 kHz
+ Target connection mode: Default
+ Reading ROM table for AP 0 @0xe00fefd0
+ Hardware watchpoint supported by the target
+ ST-LINK Firmware version : V3J9M3
+ Device ID: 0x450
+ PC: 0x8028fa4
+ ST-LINK device status: HALT_MODE
+ ST-LINK detects target voltage = 3.28 V
+ ST-LINK device status: HALT_MODE
+ ST-LINK device initialization OK
+ Stm32Device, pollAndNotify running...
+ SwvSrv state change: 0 -> 1
+ Waiting for connection on port 61235...
+ Waiting for debugger connection...
+ Waiting for connection on port 61234...
+
+In second shell window you will need to run your terminal program and
+connect to the board virtual serial port. Following steps describes
+how to do that on the Ubuntu 20.04. The recommended way here is to use minicom. Let's install it
+first by:
+
+.. code-block:: shell
+
+ $ sudo apt install minicom
+
+And run it with root privileges to be able to reach USB serial port
+provided by board:
+
+.. code-block:: shell
+
+ $ sudo minicom -s
+
+The minicom is invoked with configuration menu open. Go into the
+*Serial port setup* and hit *a* key to select *Serial Device*
+setup. Change */dev/modem* from there into */dev/ttyACM0* and hit
+*Enter* key. Hit *f* key to change hardware flow control from *Yes* to
+*No*. When you are done with it, you can hit *Enter* key to finish
+this part of configuration and then scrolls in menu to *Exit* and hit
+*Enter* key on it. The minicom will switch to terminal mode with just
+provided configuration.
+
+In the third shell window navigate into the BSP build directory and start
+RTEMS GDB with the hello.exe sample.
+
+.. code-block:: shell
+
+ $ arm-rtems6-gdb build/arm/stm32h747i-disco/testsuites/samples/hello.exe
+ GNU gdb (GDB) 10.1.90.20210409-git
+ Copyright (C) 2021 Free Software Foundation, Inc.
+ License GPLv3+: GNU GPL version 3 or later <http://gnu.org/licenses/gpl.html>
+ This is free software: you are free to change and redistribute it.
+ There is NO WARRANTY, to the extent permitted by law.
+ Type "show copying" and "show warranty" for details.
+ This GDB was configured as "--host=x86_64-linux-gnu --target=arm-rtems6".
+ Type "show configuration" for configuration details.
+ For bug reporting instructions, please see:
+ <https://www.gnu.org/software/gdb/bugs/>.
+ Find the GDB manual and other documentation resources online at:
+ <http://www.gnu.org/software/gdb/documentation/>.
+
+ For help, type "help".
+ Type "apropos word" to search for commands related to "word"...
+ Reading symbols from build/arm/stm32h747i-disco/testsuites/samples/hello.exe...
+ (gdb)
+
+Now, you need to connect GDB with the ST's GDB server by:
+
+.. code-block:: shell
+
+ (gdb) target extended-remote :61234
+ Remote debugging using :61234
+ 0x08028fa4 in ?? ()
+ (gdb)
+
+and finally you will need to load hello.exe binary into the board
+memory by:
+
+.. code-block:: shell
+
+ (gdb) load
+ Loading section .start, size 0x458 lma 0x24000000
+ Loading section .text, size 0xfca8 lma 0x24000480
+ Loading section .init, size 0xc lma 0x24010128
+ Loading section .fini, size 0xfecc lma 0x24010134
+ Loading section .rodata, size 0x1aab lma 0x24020000
+ Loading section .ARM.exidx, size 0x8 lma 0x24021aac
+ Loading section .eh_frame, size 0x4 lma 0x24021ab4
+ Loading section .init_array, size 0x4 lma 0x24021ab8
+ Loading section .fini_array, size 0x4 lma 0x24021abc
+ Loading section .rtemsroset, size 0x540 lma 0x24021ac0
+ Loading section .data, size 0x6a4 lma 0x24022000
+ Start address 0x24000400, load size 140923
+ Transfer rate: 684 KB/sec, 2562 bytes/write.
+ (gdb)
+
+If everything went fine, then you can run the RTEMS binary by using
+*cont* GDB command.
+
+.. note:: Memory address values in the load output in the gdb shows
+ that we have loaded our application into the AXI
+ SRAM. Memory addresses will be different when loading into
+ different part of MCU memory.
+
+.. code-block:: shell
+
+ (gdb) cont
+ Continuing.
+
+Note that this command should never finish. To see the actual output
+from RTEMS switch to
+the second shell window with minicom (or other terminal emulation
+program) running and you should see hello output
+there:
+
+.. code-block:: none
+
+ *** BEGIN OF TEST HELLO WORLD ***
+ *** TEST VERSION: 6.0.0.50ce036cfbd9807a54af47eb60eadb6a33a9e82d
+ *** TEST STATE: EXPECTED_PASS
+ *** TEST BUILD:
+ *** TEST TOOLS: 10.3.1 20220224 (RTEMS 6, RSB 49e3dac17765fa82ce2f754da839638ee352f95c, Newlib 64b2081)
+ Hello World
+
+ *** END OF TEST HELLO WORLD ***
+
+
+ [ RTEMS shutdown ]
+ RTEMS version: 6.0.0.50ce036cfbd9807a54af47eb60eadb6a33a9e82d
+ RTEMS tools: 10.3.1 20220224 (RTEMS 6, RSB 49e3dac17765fa82ce2f754da839638ee352f95c, Newlib 64b2081)
+ executing thread ID: 0x08a010001
+
+Since default RTEMS BSP configuration resets the board after run
+immediately you can also see output from the immediately started ST
+demo:
+
+.. code-block:: none
+
+ STM32H747I-DISCO_MB1248: Out Of the Box Demonstration V1.0.1 (Build Aug 22 2019 at 11:56:22)
+ STM32H747I-DISCO_MB1248: ST Menu Launcher V1.1.0
+ CPU running at 400MHz, Peripherals at 100MHz/100Mz
+
+which is not a problem here at all. Later we can reconfigure BSP to
+not reset board to prevent demo output here.
+
+How to load binary file into the QSPI NOR
+^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
+Connect the board to your host computer using micro-USB
+cable. Start STM32CubeProgrammer and connect it to the board by
+clicking on *Connect* button which is located in the right upper
+corner of the programmer application UI. For accessing QSPI connected
+memory you will need to configure programmer's external loader which
+needs to match your target board. Click on *EL* icon (or *External
+loaders*) in the left sidebar menu. Either go thorough the list of
+external loaders or just search for your board by typing board
+name (or part of the name) into the search bar located on top of the table view. When
+you find your board, select it by selecting rectangle in the *Select*
+table column. That's what is needed to make programmer ready to
+program your board memory.
+For uploading file to the board, you need to continue with clicking on
+*Erase & programming* menu item in the left sidebar menu. It's second item
+from the top. Now, let's select
+your file to upload by clicking on *Browse* button and selecting the
+file name from your host computer filesystem. The most important thing here is
+to specify start address of flashing process. You need to do that by
+typing start address into the *Start address* field.
+
+.. note:: Usually external memory connected to QSPI has 0x90000000 starting
+ address.
+
+When all is set you can click on *Start Programming* button.
+
+.. important:: Cube programmer is very picky about files it shows in the file list. The only recognized suffixes are: elf, bin, hex and
+ similar. Also do not try to fool programmer by renaming let's say text
+ file to bin file. It'll detect file type as ascii text and will not
+ show it in the list of files to flash. So bin file type is really for
+ media types like avi, jpeg, mpeg or for binary dumps from elf
+ files. If you need to save text file, convert it to hex file first.
diff --git a/user/bsps/arm/xen.rst b/user/bsps/arm/xen.rst
index c7085ce..d7538f0 100644
--- a/user/bsps/arm/xen.rst
+++ b/user/bsps/arm/xen.rst
@@ -42,13 +42,13 @@ The ``ticker.exe`` file can be found in the BSP build tree at:
.. code-block:: none
- arm-rtems5/c/xen_virtual/testsuites/samples/ticker.exe
+ arm-rtems@rtems-ver-major@/c/xen_virtual/testsuites/samples/ticker.exe
The ``ticker.exe`` elf file must be translated to a binary format.
.. code-block:: none
- arm-rtems5-objcopy -O binary ticker.exe ticker.bin
+ arm-rtems@rtems-ver-major@-objcopy -O binary ticker.exe ticker.bin
Then place the ``ticker.bin`` file on the dom0 filesystem.
diff --git a/user/bsps/arm/xilinx-zynq.rst b/user/bsps/arm/xilinx-zynq.rst
index 29f9cb0..0ac4487 100644
--- a/user/bsps/arm/xilinx-zynq.rst
+++ b/user/bsps/arm/xilinx-zynq.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2020 Chris Johns (chrisj@rtems.org)
+.. Copyright (C) 2015, 2020 Chris Johns (chrisj@rtems.org)
xilinx-zynq
===========
@@ -49,6 +49,22 @@ tools or a bootloader will be overwritten.
The settings for the console driver can be changed by the user
application through the termios API afterwards.
+Network
+-------
+
+The Cadence network interface driver of LibBSD works on the Xilinx Zynq
+platform. The hardware checksum support works on real hardware but does not
+seem to be supported on Qemu therefore the default state is to disable
+``IFCAP_TXCSUM`` and ``IFCAP_RXCSUM`` and this can be enabled from the shell
+with:
+
+.. code-block:: none
+
+ ifconfig cgem0 rxcsum txcsum
+
+or with an ``ioctl()`` call to the network interface driver with ``SIOCSIFCAP``
+and the mask ``IFCAP_TXCSUM`` and ``IFCAP_RXCSUM`` set.
+
Debugging with xilinx_zynq_a9_qemu
----------------------------------
diff --git a/user/bsps/arm/xilinx-zynqmp-rpu.rst b/user/bsps/arm/xilinx-zynqmp-rpu.rst
new file mode 100644
index 0000000..a29cb84
--- /dev/null
+++ b/user/bsps/arm/xilinx-zynqmp-rpu.rst
@@ -0,0 +1,76 @@
+.. SPDX-License-Identifier: CC-BY-SA-4.0
+
+.. Copyright (C) 2024 On-Line Applications Research Corporation (OAR)
+
+.. _BSP_arm_xilinx_zynqmp_rpu:
+
+Xilinx ZynqMP RPU
+=================
+
+This BSP supports the Cortex-R5 processor on the Xilinx Zynq UltraScale+ MPSoC
+platform. Basic hardware initialization is performed by the Cortex-R5 FSBL and
+the BSP. This BSP supports the GICv2 interrupt controller available to the
+Cortex-R5 subsystem. Since the Cortex-R5 subsystem only varies in speed, this
+BSP should be functional across all chip variants as well as on Xilinx's QEMU
+branch. SMP operation is not currently supported.
+
+Clock Driver
+------------
+
+The clock driver uses one of the available triple timer counters (TTCs) as the
+timer interrupt source.
+
+Console Driver
+--------------
+
+The console driver supports the default Qemu emulated ARM PL011 PrimeCell UART
+as well as the physical ARM PL011 PrimeCell UART in the ZynqMP hardware.
+
+Boot on ZynqMP Hardware
+-----------------------
+
+On the ZynqMP RPU, RTEMS can be started by Cortes-R5 u-boot, Cortex-A53 u-boot,
+via JTAG, or directly as part of BOOT.bin. For quick turnaround during testing,
+it is recommended to use Cortex-A53 u-boot to avoid repeated BOOT.bin
+generation since the provided Cortex-R5 u-boot is highly limited and has no
+network or MMC/SD access.
+
+Note that if the RPU image is started by the Cortex-A53 u-boot, the BSP
+configuration must be updated to move ZYNQMP_RPU_RAM_INT_0_ORIGIN and
+ZYNQMP_RPU_RAM_INT_1_ORIGIN into DDR since the TCMs are not directly available
+to the Cortex-A53 cores at their Cortex-R5 internal addresses. Alternatively,
+those sections could be copied to the TCMs using their global addresses, but
+this must be done using additional commands within u-boot. If this is not taken
+into account, the Cortex-R5 CPU will fail to boot correctly since execution
+will jump into uninitialized TCM.
+
+Hardware Boot Image Generation
+------------------------------
+
+When generating BOOT.bin from components, the BIF file should include at least
+entries for the Cortex-R5 FSBL ([bootloader,destination_cpu=r5-0]) and the
+Cortex-R5 application ([destination_cpu=r5-0]). The Cortex-R5 application should
+be either a u-boot or RTEMS ELF binary. The Cortex-R5 u-boot binary can be
+obtained by building it from Xilinx's u-boot repository. The Cortex-R5 FSBL can
+be obtained setting up an appropriate platform project in Xilinx's current
+development system.
+
+Boot on QEMU
+------------
+The executable image is booted by Qemu in ELF format.
+
+Running Executables on QEMU
+---------------------------
+
+Xilinx's qemu-devicetrees repository must be used in conjunction with the Xilinx
+QEMU available via RSB. Executables generated by this BSP can be run using the
+following command:
+
+.. code-block:: shell
+
+ qemu-system-aarch64 -no-reboot -nographic -M arm-generic-fdt -serial null \
+ -serial mon:stdio -device loader,file=example.exe,cpu-num=4 \
+ -device loader,addr=0xff5e023c,data=0x80088fde,data-len=4 \
+ -device loader,addr=0xff9a0000,data=0x80000218,data-len=4 \
+ -hw-dtb /xlnx-qemu-devtrees-path/LATEST/SINGLE_ARCH/board-zynqmp-zcu102.dtb \
+ -m 4096 -display none
diff --git a/user/bsps/arm/xilinx-zynqmp.rst b/user/bsps/arm/xilinx-zynqmp.rst
index 9a605bb..fa60470 100644
--- a/user/bsps/arm/xilinx-zynqmp.rst
+++ b/user/bsps/arm/xilinx-zynqmp.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2019 embedded brains GmbH
+.. Copyright (C) 2019 embedded brains GmbH & Co. KG
xilinx-zynqmp
=============
diff --git a/user/bsps/bsps-aarch64.rst b/user/bsps/bsps-aarch64.rst
index 933370f..f99843a 100644
--- a/user/bsps/bsps-aarch64.rst
+++ b/user/bsps/bsps-aarch64.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
aarch64 (AArch64)
*****************
@@ -9,3 +9,4 @@ aarch64 (AArch64)
.. include:: aarch64/a72.rst
.. include:: aarch64/xilinx-versal.rst
.. include:: aarch64/xilinx-zynqmp.rst
+.. include:: aarch64/raspberrypi4.rst \ No newline at end of file
diff --git a/user/bsps/bsps-arm.rst b/user/bsps/bsps-arm.rst
index 7f1e9d4..bd335fa 100644
--- a/user/bsps/bsps-arm.rst
+++ b/user/bsps/bsps-arm.rst
@@ -1,30 +1,34 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2017, 2019 embedded brains GmbH
+.. Copyright (C) 2017, 2019 embedded brains GmbH & Co. KG
.. Copyright (C) 2017, 2019 Sebastian Huber
arm (ARM)
*********
-.. include:: arm/altera-cyclone-v.rst
-.. include:: arm/atsam.rst
-.. include:: arm/beagle.rst
-.. include:: arm/csb336.rst
-.. include:: arm/csb337.rst
-.. include:: arm/edb7312.rst
-.. include:: arm/gumstix.rst
-.. include:: arm/imx.rst
-.. include:: arm/imxrt.rst
-.. include:: arm/lm3s69xx.rst
-.. include:: arm/lpc176x.rst
-.. include:: arm/lpc24xx.rst
-.. include:: arm/raspberrypi.rst
-.. include:: arm/realview-pbx-a9.rst
-.. include:: arm/rtl22xx.rst
-.. include:: arm/smdk2410.rst
-.. include:: arm/stm32f4.rst
-.. include:: arm/stm32h7.rst
-.. include:: arm/tms570.rst
-.. include:: arm/xen.rst
-.. include:: arm/xilinx-zynq.rst
-.. include:: arm/xilinx-zynqmp.rst
+.. toctree::
+
+ arm/altera-cyclone-v.rst
+ arm/atsam.rst
+ arm/beagle.rst
+ arm/csb336.rst
+ arm/csb337.rst
+ arm/edb7312.rst
+ arm/fvp.rst
+ arm/gumstix.rst
+ arm/imx.rst
+ arm/imxrt.rst
+ arm/lm3s69xx.rst
+ arm/lpc176x.rst
+ arm/lpc24xx.rst
+ arm/raspberrypi.rst
+ arm/realview-pbx-a9.rst
+ arm/rtl22xx.rst
+ arm/smdk2410.rst
+ arm/stm32f4.rst
+ arm/stm32h7.rst
+ arm/tms570.rst
+ arm/xen.rst
+ arm/xilinx-zynq.rst
+ arm/xilinx-zynqmp.rst
+ arm/xilinx-zynqmp-rpu.rst
diff --git a/user/bsps/bsps-bfin.rst b/user/bsps/bsps-bfin.rst
index db7f721..eeb426e 100644
--- a/user/bsps/bsps-bfin.rst
+++ b/user/bsps/bsps-bfin.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
bfin (Blackfin)
***************
diff --git a/user/bsps/bsps-i386.rst b/user/bsps/bsps-i386.rst
index 0b273ee..81f5fd8 100644
--- a/user/bsps/bsps-i386.rst
+++ b/user/bsps/bsps-i386.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
i386
****
diff --git a/user/bsps/bsps-lm32.rst b/user/bsps/bsps-lm32.rst
index 2db5b12..98ffb91 100644
--- a/user/bsps/bsps-lm32.rst
+++ b/user/bsps/bsps-lm32.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
lm32 (LatticeMicro32)
*********************
diff --git a/user/bsps/bsps-m68k.rst b/user/bsps/bsps-m68k.rst
index bdb516b..a820d96 100644
--- a/user/bsps/bsps-m68k.rst
+++ b/user/bsps/bsps-m68k.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
m68k (Motorola 68000 / ColdFire)
********************************
diff --git a/user/bsps/bsps-microblaze.rst b/user/bsps/bsps-microblaze.rst
index e20df53..6fe4891 100644
--- a/user/bsps/bsps-microblaze.rst
+++ b/user/bsps/bsps-microblaze.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
.. Copyright (C) 2022 On-Line Applications Research Corporation (OAR)
microblaze (MicroBlaze)
@@ -21,13 +21,21 @@ Clock Driver
------------
The clock driver supports the QEMU emulated Xilinx AXI Timer v2.0. It is
-implemented as a simple downcounter.
+implemented as a simple downcounter. If device tree support is enabled in the
+build configuration, the clock driver will use the node that is compatible with
+`xlnx,xps-timer-1.00.a` from the device tree to configure the clock. The
+following device tree node properties are used to configure the clock driver:
+``reg``, ``clock-frequency``, and ``interrupts``.
Console Driver
--------------
The console driver supports the QEMU emulated Xilinx AXI UART Lite v2.0. It is
-initialized to a baud rate of 115200.
+initialized to a baud rate of 115200. If device tree support is enabled in the
+build configuration, the console driver will use the node that is compatible
+with `xlnx,xps-uartlite-1.00.a` from the device tree to configure the console.
+The following device tree node properties are used to configure the console
+driver: ``reg``, ``status``, ``port-number``, and ``interrupts``.
Network Driver
--------------
@@ -53,18 +61,30 @@ The name ``system_dtb`` is significant as it is the name expected by the BSP.
$ rtems-bin2c -C -A 8 -N system_dtb my_device_tree.dtb my_dtb
The ``BSP_MICROBLAZE_FPGA_DTB_HEADER_PATH`` BSP configuration option can then be
-set to the path of the resulting source file, ``my_dtb.c``, to include it in the
-BSP build.
+set to the path of the resulting source file, ``my_dtb.c``, in the waf INI file
+to include it in the BSP build.
.. code-block:: none
BSP_MICROBLAZE_FPGA_DTB_HEADER_PATH = /path/to/my_dtb.c
+QSPI NOR JFFS2 Driver
+---------------------
+
+The QSPI NOR JFFS2 driver supports the QEMU emulated n25q512a11 QSPI NOR flash
+device. It is initialized to a page size of 256 bytes and a sector size of 64
+KiB. If device tree support is enabled in the build configuration, the QSPI NOR
+JFFS2 driver will use the node that is compatible with `xlnx,xps-spi-2.00.a`
+from the device tree to configure the QSPI NOR JFFS2 driver. The following
+device tree node properties are used to configure the QSPI NOR JFFS2 driver:
+``reg`` and ``interrupts``.
+
+
Running Executables
-------------------
-A .dtb (device tree blob) file should be provided to QEMU via the ``-hw-dtb``
+A ``.dtb`` (device tree blob) file should be provided to QEMU via the ``-hw-dtb``
option. In the example command below, the device tree blob comes from the Xilinx
Petalinux KCU105 MicroBlaze BSP (https://www.xilinx.com/support/download/index.html/content/xilinx/en/downloadNav/embedded-design-tools.html).
@@ -94,7 +114,7 @@ Then start GDB and connect to QEMU.
.. code-block:: none
- $ microblaze-rtems6-gdb build/microblaze/kcu105_qemu/testsuites/samples/hello.exe
+ $ microblaze-rtems@rtems-ver-major@-gdb build/microblaze/kcu105_qemu/testsuites/samples/hello.exe
(gdb) target remote localhost:1234
(gdb) break Init
(gdb) continue
@@ -114,12 +134,21 @@ Clock Driver
------------
The clock driver supports the Xilinx AXI Timer v2.0. It is implemented as a
-simple downcounter.
+simple downcounter. If device tree support is enabled in the
+build configuration, the clock driver will use the node that is compatible with
+`xlnx,xps-timer-1.00.a` from the device tree to configure the clock. The
+following device tree node properties are used to configure the clock driver:
+``reg``, ``clock-frequency``, and ``interrupts``.
Console Driver
--------------
-The console driver supports the Xilinx AXI UART Lite v2.0.
+The console driver supports the Xilinx AXI UART Lite v2.0. It is initialized to
+a baud rate of 115200. If device tree support is enabled in the build
+configuration, the console driver will use the node that is compatible with
+`xlnx,xps-uartlite-1.00.a` from the device tree to configure the console. The
+following device tree node properties are used to configure the console driver:
+``reg``, ``status``, ``port-number``, and ``interrupts``.
Debugging
---------
@@ -146,7 +175,7 @@ application, and debug as usual. By default the GDB server listens on port 3002.
.. code-block:: none
- $ microblaze-rtems6-gdb example.exe
+ $ microblaze-rtems@rtems-ver-major@-gdb example.exe
(gdb) target extended-remote localhost:3002
(gdb) load
(gdb) break Init
diff --git a/user/bsps/bsps-mips.rst b/user/bsps/bsps-mips.rst
index 9f83811..f90732a 100644
--- a/user/bsps/bsps-mips.rst
+++ b/user/bsps/bsps-mips.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
mips (MIPS)
***********
diff --git a/user/bsps/bsps-moxie.rst b/user/bsps/bsps-moxie.rst
index eab88cc..8548777 100644
--- a/user/bsps/bsps-moxie.rst
+++ b/user/bsps/bsps-moxie.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
moxie
*****
diff --git a/user/bsps/bsps-nios2.rst b/user/bsps/bsps-nios2.rst
index ad21dd3..5280025 100644
--- a/user/bsps/bsps-nios2.rst
+++ b/user/bsps/bsps-nios2.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
nios2 (Nios II)
***************
diff --git a/user/bsps/bsps-or1k.rst b/user/bsps/bsps-or1k.rst
index 6295c23..e7d9a10 100644
--- a/user/bsps/bsps-or1k.rst
+++ b/user/bsps/bsps-or1k.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
or1k (OpenRISC 1000)
********************
diff --git a/user/bsps/bsps-powerpc.rst b/user/bsps/bsps-powerpc.rst
index 80edfae..6b63936 100644
--- a/user/bsps/bsps-powerpc.rst
+++ b/user/bsps/bsps-powerpc.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
powerpc (PowerPC)
*****************
@@ -36,10 +36,10 @@ image. Use the following commands:
.. code-block:: none
- powerpc-rtems5-objcopy -O binary -R .comment -S ticker.exe rtems
+ powerpc-rtems@rtems-ver-major@-objcopy -O binary -R .comment -S ticker.exe rtems
gzip -9 -f rtems
- powerpc-rtems5-ld -o ticker.boot bootloader.o --just-symbols=ticker.exe -b binary rtems.gz -T ppcboot.lds -no-warn-mismatch
- powerpc-rtems5-objcopy -O binary ticker.boot ticker.bin
+ powerpc-rtems@rtems-ver-major@-ld -o ticker.boot bootloader.o --just-symbols=ticker.exe -b binary rtems.gz -T ppcboot.lds -no-warn-mismatch
+ powerpc-rtems@rtems-ver-major@-objcopy -O binary ticker.boot ticker.bin
mpc55xxevb
==========
@@ -107,7 +107,7 @@ image. Use the following commands:
.. code-block:: none
- powerpc-rtems5-objcopy -O binary app.exe app.bin
+ powerpc-rtems@rtems-ver-major@-objcopy -O binary app.exe app.bin
gzip -9 -f -c app.bin > app.bin.gz
mkimage -A ppc -O linux -T kernel -a 0x4000 -e 0x4000 -n RTEMS -d app.bin.gz app.img
diff --git a/user/bsps/bsps-riscv.rst b/user/bsps/bsps-riscv.rst
index 0799ad6..263796e 100644
--- a/user/bsps/bsps-riscv.rst
+++ b/user/bsps/bsps-riscv.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
riscv (RISC-V)
**************
@@ -8,7 +8,8 @@ riscv (RISC-V)
riscv
=====
-This BSP offers 13 variants:
+**Each variant in this first group corresponds to a GCC multilib option with
+different RISC-V standard extensions.**
* rv32i
@@ -26,31 +27,36 @@ This BSP offers 13 variants:
* rv64imac
-* rv64imac_medany
-
* rv64imafd
-* rv64imafd_medany
-
* rv64imafdc
-* rv64imafdc_medany
+Each variant reflects an ISA with ABI and code model choice. All rv64 BSPs have
+medany code model by default, while rv32 BSPs are medlow. The reason is that
+RV32 medlow can access the entire 32-bit address space, while RV64 medlow can
+only access addresses below 0x80000000. With RV64 medany, it's possible to
+perform accesses above 0x80000000. The BSP must be started in machine mode.
+
+The reference platforms for the rv* variants include the QEMU `virt` and
+`spike` machines and the Spike RISC-V ISA simulator.
+
+**The BSP also provides the following variants for specific hardware targets:**
-* frdme310arty
+* frdme310arty - The reference platform for this variant is the Arty FPGA board
+ with the SiFive Freedom E310 reference design.
-Each variant corresponds to a GCC multilib. A particular variant reflects an
-ISA with ABI and code model choice.
+* mpfs64imafdc - The reference platform for this variant is the Microchip
+ PolarFire SoC Icicle Kit.
-The basic hardware initialization is not performed by the BSP. A boot loader
-with device tree support must be used to start the BSP, e.g. BBL. The BSP must
-be started im machine mode.
+* kendrytek210 - The reference platform for this variant is the Kendryte K210
+ SoC on the Sipeed MAiX BiT or Maixduino board.
-The reference platform for this BSP is the Qemu `virt` machine.
Build Configuration Options
---------------------------
-The following options are available at the configure command line.
+The following options can be used in the BSP section of the ``waf``
+configuration INI file. The ``waf`` defaults can be used to inspect the values.
``BSP_PRESS_KEY_FOR_RESET``
If defined to a non-zero value, then print a message and wait until pressed
@@ -67,31 +73,51 @@ The following options are available at the configure command line.
``BSP_FDT_BLOB_SIZE_MAX``
The maximum size of the device tree blob in bytes (default is 65536).
+``BSP_DTB_IS_SUPPORTED``
+ If defined to a non-zero value, then the device tree blob is embedded in
+ the BSP.
+
+``BSP_DTB_HEADER_PATH``
+ The path to the header file containing the device tree blob.
+
``BSP_CONSOLE_BAUD``
- The default baud for console driver devices (default 115200).
+ The default baud for console driver devices (default is 115200).
``RISCV_MAXIMUM_EXTERNAL_INTERRUPTS``
The maximum number of external interrupts supported by the BSP (default
- 64).
+ is 64).
``RISCV_ENABLE_HTIF_SUPPORT``
- Enables the HTIF support if defined to a non-zero value, otherwise it is
- disabled (disabled by default).
+ Enable the Host/Target Interface (HTIF) support (enabled by default).
``RISCV_CONSOLE_MAX_NS16550_DEVICES``
- The maximum number of NS16550 devices supported by the console driver (2
- by default).
+ The maximum number of NS16550 devices supported by the console driver
+ (default is 2).
+
+``RISCV_ENABLE_SIFIVE_UART_SUPPORT``
+ Enable the SiFive console UART (disabled by default).
``RISCV_RAM_REGION_BEGIN``
- The begin of the RAM region for linker command file (default is 0x70000000
- for 64-bit with -mcmodel=medlow and 0x80000000 for all other).
+ The begin of the RAM region for linker command file
+ (default is 0x80000000).
``RISCV_RAM_REGION_SIZE``
The size of the RAM region for linker command file (default 64MiB).
``RISCV_ENABLE_FRDME310ARTY_SUPPORT``
Enables support sifive Freedom E310 Arty board if defined to a non-zero
- value,otherwise it is disabled (disabled by default)
+ value,otherwise it is disabled (disabled by default).
+
+``RISCV_ENABLE_MPFS_SUPPORT``
+ Enables support Microchip PolarFire SoC if defined to a non-zero
+ value, otherwise it is disabled (disabled by default).
+
+``RISCV_ENABLE_KENDRYTE_K210_SUPPORT``
+ Enables support for the Kendtryte K210 SoC if defined to a non-zero
+ value, otherwise it is disabled (disabled by default).
+
+``RISCV_BOOT_HARTID``
+ The boot hartid (processor number) of risc-v cpu by default 0.
Interrupt Controller
--------------------
@@ -109,20 +135,341 @@ The clock driver uses the CLINT timer.
Console Driver
--------------
-The console driver supports devices compatible to
+The console driver supports devices compatible to:
* "ucb,htif0" (depending on the ``RISCV_ENABLE_HTIF_SUPPORT`` BSP option),
-* "ns16550a" (see ``RISCV_CONSOLE_MAX_NS16550_DEVICES`` BSP option), and
+* "ns16550a" (see ``RISCV_CONSOLE_MAX_NS16550_DEVICES`` BSP option),
-* "ns16750" (see ``RISCV_CONSOLE_MAX_NS16550_DEVICES`` BSP option).
+* "ns16750" (see ``RISCV_CONSOLE_MAX_NS16550_DEVICES`` BSP option), and
-* "sifive,uart0" (see ``RISCV_ENABLE_FRDME310ARTY_SUPPORT`` BSP option).
+* "sifive,uart0" (see ``RISCV_ENABLE_SIFIVE_UART_SUPPORT`` BSP option).
They are initialized according to the device tree. The console driver does not
configure the pins or peripheral clocks. The console device is selected
according to the device tree "/chosen/stdout-path" property value.
+QEMU
+----
+
+All of the BSP variants that start with rv can be run on QEMU's virt
+and spike machines. For instance, to run the ``rv64imafdc`` BSP with the
+following "config.ini" file.
+
+.. code-block:: none
+
+ [riscv/rv64imafdc]
+
+Run the following QEMU command.
+
+.. code-block:: shell
+
+ $ qemu-system-riscv64 -M virt -nographic -bios $RTEMS_EXE
+ $ qemu-system-riscv64 -M spike -nographic -bios $RTEMS_EXE
+
+Spike
+----
+
+All of the BSP variants that start with rv can be run on Spike. For instance,
+to run the ``rv64imafdc`` BSP with the following "config.ini" file.
+
+.. code-block:: none
+
+ [riscv/rv64imafdc]
+
+Run the following Spike command.
+
+.. code-block:: shell
+
+ $ spike --isa=rv64imafdc $RTEMS_EXE
+
+Unlike QEMU, Spike supports enabling/disabling a subset of the imafdc
+extensions and has support for further RISC-V extensions as well. A fault will
+be triggered if an executable built with rv64imafdc RISC-V's -march option run
+on Spike with --isa=rv64i option. If no --isa option is specified, the default
+is rv64imafdc.
+
+Microchip PolarFire SoC
+-----------------------
+
+The PolarFire SoC is the 4x 64-bit RISC-V U54 cores and a 64-bit RISC-V E51
+monitor core SoC from the Microchip.
+
+The ``mpfs64imafdc`` BSP variant supports the U54 cores but not the E51 because
+the E51 monitor core is reserved for the first stage bootloader (Hart Software
+Services). In order to boot from the first U54 core, ``RISCV_BOOT_HARTID`` is
+set to 1 by default.
+
+The device tree blob is embedded in the ``mpfs64imafdc`` BSP variant by default
+with the ``BSP_DTB_IS_SUPPORTED`` enabled and the DTB header path
+``BSP_DTB_HEADER_PATH`` is set to bsp/mpfs-dtb.h.
+
+**SMP test procedure for the Microchip PolarFire Icicle Kit:**
+
+The "config.ini" file.
+
+.. code-block:: none
+
+ [riscv/mpfs64imafdc]
+ BUILD_TESTS = True
+ RTEMS_POSIX_API=True
+ RTEMS_SMP = True
+ BSP_START_COPY_FDT_FROM_U_BOOT=False
+ BSP_VERBOSE_FATAL_EXTENSION = False
+
+Build RTEMS.
+
+.. code-block:: shell
+
+ $ ./waf configure --prefix=$HOME/rtems-start/rtems/@rtems-ver-major@
+ $ ./waf
+
+Convert .exe to .elf file.
+
+.. code-block:: shell
+
+ $ riscv-rtems@rtems-ver-major@-objcopy build/riscv/mpfs64imafdc/testsuites/smptests/smp01.exe build/riscv/mpfs64imafdc/testsuites/smptests/smp01.elf
+
+Generate a payload for the `smp01.elf` using the `hss-payload-generator <https://github.com/polarfire-soc/hart-software-services/blob/master/tools/hss-payload-generator>`_.
+
+* Copy `smp01.elf` file to the HSS/tools/hss-payload-generator/test directory.
+
+* Go to hss-payload-generator source directory.
+
+.. code-block:: shell
+
+ $ cd hart-software-services/tools/hss-payload-generator
+
+* Edit test/uboot.yaml file for the hart entry points and correct name of the
+ binary file.
+
+.. code-block:: none
+
+ set-name: 'PolarFire-SoC-HSS::RTEMS'
+ hart-entry-points: {u54_1: '0x1000000000', u54_2: '0x1000000000', u54_3: '0x1000000000', u54_4: '0x1000000000'}
+ payloads:
+ test/smp01.elf: {exec-addr: '0x1000000000', owner-hart: u54_1, secondary-hart: u54_2, secondary-hart: u54_3, secondary-hart: u54_4, priv-mode: prv_m, skip-opensbi: true}
+
+* Generate payload
+
+.. code-block:: shell
+
+ $ ./hss-payload-generator -c test/uboot.yaml payload.bin
+
+Once the payload binary is generated, it should be copied to the eMMC/SD.
+
+`FPGA design with HSS programming file <https://github.com/polarfire-soc/polarfire-soc-documentation/blob/master/boards/mpfs-icicle-kit-es/updating-icicle-kit/updating-icicle-kit-design-and-linux.md>`_.
+
+Program the eMMC/SD with the payload binary.
+
+* Power Cycle the Microchip PolarFire Icicle Kit and stop at the HSS.
+
+* type "mmc" and then "usbdmsc" on the HSS terminal(UART0).
+
+* Load the payload.bin from the Host PC.
+
+.. code-block:: shell
+
+ $ sudo dd if=payload.bin of=/dev/sdb bs=512
+
+Reset the Microchip PolarFire SoC Icicle Kit.
+
+Serial terminal UART1 displays the SMP example messages
+
+.. code-block:: none
+
+ *** BEGIN OF TEST SMP 1 ***
+ *** TEST VERSION: 6.0.0.ef33f861e16de9bf4190a36e4d18062c7300986c
+ *** TEST STATE: EXPECTED_PASS
+ *** TEST BUILD: RTEMS_POSIX_API RTEMS_SMP
+ *** TEST TOOLS: 12.1.1 20220622 (RTEMS 6, RSB 3cb78b0b815ba05d17f5c6
+ 5865d246a8333aa087, Newlib ea99f21)
+
+ CPU 3 start task TA0
+ CPU 2 running Task TA0
+ CPU 3 start task TA1
+ CPU 1 running Task TA1
+ CPU 3 start task TA2
+ CPU 0 running Task TA2
+
+ *** END OF TEST SMP 1 ***
+
+Kendryte K210
+-------------
+
+The Kendryte K210 SoC is a dual core 64-bit RISC-V SoC with an AI NPU, built in
+SRAM, and a variety of peripherals. Currently just the console UART, interrupt
+controller, and timer are supported.
+
+The device tree blob is embedded in the ``kendrytek210`` BSP variant by
+default. When the kendrytek210 BSP variant is selected,
+``BSP_DTB_IS_SUPPORTED`` enabled and the DTB header path
+``BSP_DTB_HEADER_PATH`` is set to ``bsp/kendryte-k210-dtb.h``.
+
+The ``kendrytek210`` BSP variant has been tested on the following simulator and
+boards:
+
+* Renode.io simulator using the Kendrtye k210 model
+* Sipeed MAiX BiT board
+* Sipeed Maixduino board
+* Sipeed MAiX Dock board
+
+**Building the Kendryte K210 BSP**
+
+Configuration file ``config.ini``:
+
+.. code-block:: none
+
+ [riscv/kendrytek210]
+ RTEMS_SMP = True
+
+Build RTEMS:
+
+.. code-block:: shell
+
+ $ ./waf configure --prefix=$HOME/rtems-start/rtems/@rtems-ver-major@
+ $ ./waf
+
+**Flash an executable to a supported K210 board**
+
+Binary images can be flashed to the Sipeed boards through the USB port using
+the ``kflash.py`` utility available from the python pip utility.
+
+.. code-block:: shell
+
+ $ riscv-rtems@rtems-ver-major@-objcopy -Obinary ticker.exe ticker.bin
+ $ kflash.py --uart /dev/ttyUSB0 ticker.bin
+
+After the image is flashed, the RTEMS image will automatically boot. It will
+also run when the board is reset or powered through the USB cable. The USB port
+provides the power and console UART. Plug the USB cable into a host PC and
+bring up a terminal emulator at 115200 baud, 8 data bits, 1 stop bit, no
+parity, and no flow control. On Linux the UART device is often
+``/dev/ttyUSB0``.
+
+**Run a RTEMS application on the Renode.io simulator**
+
+RTEMS executables compiled with the kendrytek210 BSP can run on the renode.io
+simulator using the built-in K210 model. The simulator currently supports the
+console UART, interrupt controller, and timer.
+
+To install renode.io please refer to the `installation instructions <https://github.com/renode/renode#installation>`_.
+Once installed, save the following file as `k210_rtems.resc`.
+
+.. code-block:: shell
+
+ using sysbus
+
+ $bin?=@ticker.exe
+
+ mach create "K210"
+
+ machine LoadPlatformDescription @platforms/cpus/kendryte_k210.repl
+
+ showAnalyzer uart
+
+ sysbus Tag <0x50440000 0x10000> "SYSCTL"
+ sysbus Tag <0x50440018 0x4> "pll_lock" 0xFFFFFFFF
+ sysbus Tag <0x5044000C 0x4> "pll1"
+ sysbus Tag <0x50440008 0x4> "pll0"
+ sysbus Tag <0x50440020 0x4> "clk_sel0"
+ sysbus Tag <0x50440028 0x4> "clk_en_cent"
+ sysbus Tag <0x5044002c 0x4> "clk_en_peri"
+
+ macro reset
+ """
+ sysbus LoadELF $bin
+ """
+ runMacro $reset
+
+After saving the above file in in the same directory as your RTEMS ELF images,
+start renode and load the `k210_rtems.resc` script to start the emulation.
+
+.. code-block:: shell
+
+ (monitor) s @k210_rtems.resc
+
+You should see a renode UART window and the RTEMS ticker example output. If you
+want to run a different RTEMS image, you can edit the file or enter the
+following on the renode console.
+
+.. code-block:: shell
+
+ (monitor) $bin=@smp08.exe
+ (monitor) s @k210_rtems.resc
+
+The above example will run the SMP08 example instead of ticker.
+
+**Generating the Device Tree Header**
+
+The kendrytek210 BSP uses a built in device tree blob. If additional peripheral
+support is added to the BSP, the device tree may need to be updated. After
+editing the device tree source, compile it to a device tree blob with the
+following command:
+
+.. code-block:: shell
+
+ $ dtc -O dtb -b 0 -o kendryte-k210.dtb kendryte-k210.dts
+
+The dtb file can then be converted to a C array using the rtems-bin2c tool.
+The data for the device tree binary can then replace the existing device tree
+binary data in the ``kendryte-k210-dtb.h`` header file.
+
+noel
+====
+
+This BSP supports the `NOEL-V <https://gaisler.com/noel-v>`_ systems from
+Cobham Gaisler. The NOEL-V is a synthesizable VHDL model of a processor that
+implements the RISC-V architecture. It is part of the open source `GRLIB
+<https://gaisler.com/grlib>`_ IP Library. The following BSP variants correspond
+to common NOEL-V configurations:
+
+* noel32im
+
+* noel32imafd
+
+* noel64imac
+
+* noel64imafd
+
+* noel64imafdc
+
+The start of the memory is set to 0x0 to match a standard NOEL-V system, but
+can be changed using the ``RISCV_RAM_REGION_BEGIN`` configuration option. The
+size of the memory is taken from the information available in the device tree.
+
+Reference Designs
+-----------------
+
+The BSP has been tested with NOEL-V reference designs for `Digilent Arty A7
+<https://gaisler.com/noel-artya7>`_, `Microchip PolarFire Splash Kit
+<https://gaisler.com/noel-pf>`_, and `Xilinx KCU105
+<https://gaisler.com/noel-xcku>`_. See the accompanying quickstart guide for
+each reference design to determine which BSP configuration to use.
+
+Build Configuration Options
+---------------------------
+
+The following options can be used in the BSP section of the ``waf``
+configuration INI file. The ``waf`` defaults can be used to inspect the values.
+
+``BSP_CONSOLE_USE_INTERRUPTS``
+ Use the Termios interrupt mode in the console driver (true by default).
+
+``BSP_FDT_BLOB_SIZE_MAX``
+ The maximum size of the device tree blob in bytes (262144 by default).
+
+``RISCV_CONSOLE_MAX_APBUART_DEVICES``
+ The maximum number of APBUART devices supported by the console driver
+ (2 by default).
+
+``RISCV_RAM_REGION_BEGIN``
+ The begin of the RAM region for linker command file (0x0 by default).
+
+``RISCV_MAXIMUM_EXTERNAL_INTERRUPTS``
+ The maximum number of external interrupts supported by the BSP (64 by
+ default).
+
griscv
======
diff --git a/user/bsps/bsps-sh.rst b/user/bsps/bsps-sh.rst
index b147251..8c245c4 100644
--- a/user/bsps/bsps-sh.rst
+++ b/user/bsps/bsps-sh.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
sh (SuperH)
***********
diff --git a/user/bsps/bsps-sparc.rst b/user/bsps/bsps-sparc.rst
index d0316a9..325c7fa 100644
--- a/user/bsps/bsps-sparc.rst
+++ b/user/bsps/bsps-sparc.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
.. Copyright (C) 2020 Chris Johns
sparc (SPARC / LEON)
@@ -20,11 +20,81 @@ TODO.
leon2
=====
-TODO.
+This BSP supports LEON2 systems, in particular the `Microchip AT697F
+<https://www.microchip.com/en-us/product/AT697F>`_. The following
+default build configurations are provided:
+
+* leon2 - A generic LEON2 system with memory at 0x4000000.
+
+* at697f - For the AT697F. Built with ``-mcpu=leon -mfix-at697f``.
+
+The BSP contains UART, timer, and interrupt controller drivers.
+Drivers for PCI are available through the :ref:`driver manager <BSP_sparc_leon3_drv_mgr>`.
.. _BSP_sparc_leon3:
leon3
=====
-TODO.
+This BSP supports the LEON3/4/5 systems from Cobham Gaisler.
+The following default build configurations are provided:
+
+* leon3 - A generic `LEON3/4/5 <https://www.gaisler.com/leon5>`_ system with memory at 0x4000000.
+
+* ut700 - For the `UT700 <https://caes.com/product/ut700>`_. Built with ``-mcpu=leon3 -mfix-ut700``.
+
+* ut699 - For the `UT699 <https://caes.com/product/ut699>`_. Built with ``-mcpu=leon -mfix-ut699``.
+
+* gr712rc - For the `GR712RC <https://www.gaisler.com/gr712rc>`_. Built with ``-mcpu=leon3 -mfix-gr712rc``.
+
+* gr740 - For the `GR740 <https://www.gaisler.com/gr740>`_. Memory located at address 0x0.
+
+The BSP contains UART, timer, and interrupt controller drivers. Drivers for additional
+peripherals are available through the driver manager.
+
+.. _BSP_sparc_leon3_drv_mgr:
+
+Driver Manager
+--------------
+
+The leon3 BSP includes an optional driver manager that handles drivers and
+devices on the AMBA and PCI Plug & Play buses. The driver manager can either
+be initialized manually by the user, or started automatically on startup by
+setting the ``RTEMS_DRVMGR_STARTUP`` option. It can be configured to
+automatically instantiate a driver for each hardware device found.
+
+Drivers for the following devices are provided and handled via the driver manager:
+
+* SpaceWire (GRSPW, GRSPW2, GRSPW2_DMA)
+* SpaceWire Router (GRSPWROUTER)
+* SpaceWire Time Distribution Protocol (SPWTDP)
+* CAN - non-DMA (OCCAN) and DMA (GRCAN, GRCANFD)
+- GPIO (GRGPIO)
+- L2 Cache (L2CACHE)
+- IOMMU (GRIOMMU)
+- ADC/DAC (GRADCDAC)
+- Timers (GPTIMER, GRTIMER)
+- 1553 BC, RT and BM support (GR1553B)
+- I2C Master (I2CMST)
+- PCI (GRPCI2, GRPCI, PCIF)
+- Memory Controller (MCTRL)
+- Memory Scrubber (MEMSCRUB)
+- Pulse Width Modulation Generator (GRPWM)
+- CCSDS/ECSS Telemetry Encoder/Decoder (GRTM/GRTC)
+- CSDS Time Manager (GRCTM)
+- Ethernet (GRETH 10/100/1000) (requires network stack)
+- Performance counters (L4STAT)
+- Serial Peripheral Interface (AHBSTAT)
+- AHB Status (AHBSTAT)
+
+Build Configuration Options
+---------------------------
+
+The following options can be used in the BSP section of the ``waf``
+configuration INI file. The ``waf`` defaults can be used to inspect the values.
+
+``CONSOLE_USE_INTERRUPTS``
+ Use the Termios interrupt mode in the console driver (false by default).
+
+``RTEMS_DRVMGR_STARTUP``
+ Enable the Driver Manager at startup (false by default).
diff --git a/user/bsps/bsps-sparc64.rst b/user/bsps/bsps-sparc64.rst
index e7be4ea..7b598b7 100644
--- a/user/bsps/bsps-sparc64.rst
+++ b/user/bsps/bsps-sparc64.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
sparc64 (SPARC V9)
******************
diff --git a/user/bsps/bsps-v850.rst b/user/bsps/bsps-v850.rst
index 39973db..220ccc0 100644
--- a/user/bsps/bsps-v850.rst
+++ b/user/bsps/bsps-v850.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
v850 (V850)
***********
diff --git a/user/bsps/bsps-x86_64.rst b/user/bsps/bsps-x86_64.rst
index eefffab..38d84e4 100644
--- a/user/bsps/bsps-x86_64.rst
+++ b/user/bsps/bsps-x86_64.rst
@@ -1,7 +1,7 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
.. Copyright (C) 2018 Amaan Cheval <amaan.cheval@gmail.com>
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
x86_64
******
@@ -20,7 +20,7 @@ in the RTEMS testsuite.
Build Configuration Options
---------------------------
-There are no options available to ``configure`` at build time, at the moment.
+There are no BSP configuration options available at build time.
Testing with QEMU
-----------------
diff --git a/user/bsps/index.rst b/user/bsps/index.rst
index bf590e0..5c1b3b7 100644
--- a/user/bsps/index.rst
+++ b/user/bsps/index.rst
@@ -1,6 +1,6 @@
.. SPDX-License-Identifier: CC-BY-SA-4.0
-.. Copyright (C) 2018 embedded brains GmbH
+.. Copyright (C) 2018 embedded brains GmbH & Co. KG
.. _BSPs: