docs/system/riscv/microchip-icicle-kit.rst - third_party/qemu - Git at Google

 Microchip PolarFire SoC Icicle Kit (``microchip-icicle-kit``)
 =============================================================

 Microchip PolarFire SoC Icicle Kit integrates a PolarFire SoC, with one
 SiFive's E51 plus four U54 cores and many on-chip peripherals and an FPGA.

 For more details about Microchip PolarFire SoC, please see:
 https://www.microsemi.com/product-directory/soc-fpgas/5498-polarfire-soc-fpga

 The Icicle Kit board information can be found here:
 https://www.microsemi.com/existing-parts/parts/152514

 Supported devices
 -----------------

 The ``microchip-icicle-kit`` machine supports the following devices:

 * 1 E51 core
 * 4 U54 cores
 * Core Level Interruptor (CLINT)
 * Platform-Level Interrupt Controller (PLIC)
 * L2 Loosely Integrated Memory (L2-LIM)
 * DDR memory controller
 * 5 MMUARTs
 * 1 DMA controller
 * 2 GEM Ethernet controllers
 * 1 SDHC storage controller

 Boot options
 ------------

 The ``microchip-icicle-kit`` machine can start using the standard -bios
 functionality for loading its BIOS image, aka Hart Software Services (HSS_).
 HSS loads the second stage bootloader U-Boot from an SD card. Then a kernel
 can be loaded from U-Boot. It also supports direct kernel booting via the
 -kernel option along with the device tree blob via -dtb. When direct kernel
 boot is used, the OpenSBI fw_dynamic BIOS image is used to boot a payload
 like U-Boot or OS kernel directly.

 The user provided DTB should have the following requirements:

 * The /cpus node should contain at least one subnode for E51 and the number
   of subnodes should match QEMU's ``-smp`` option
 * The /memory reg size should match QEMU’s selected ram_size via ``-m``
 * Should contain a node for the CLINT device with a compatible string
   "riscv,clint0"

 QEMU follows below truth table to select which payload to execute:

 ===== ========== ========== =======
 -bios    -kernel       -dtb payload
 ===== ========== ========== =======
     N          N don't care     HSS
     Y don't care don't care     HSS
     N          Y          Y  kernel
 ===== ========== ========== =======

 The memory is set to 1537 MiB by default which is the minimum required high
 memory size by HSS. A sanity check on ram size is performed in the machine
 init routine to prompt user to increase the RAM size to > 1537 MiB when less
 than 1537 MiB ram is detected.

 Running HSS
 -----------

 HSS 2020.12 release is tested at the time of writing. To build an HSS image
 that can be booted by the ``microchip-icicle-kit`` machine, type the following
 in the HSS source tree:

 .. code-block:: bash

   $ export CROSS_COMPILE=riscv64-linux-
   $ cp boards/mpfs-icicle-kit-es/def_config .config
   $ make BOARD=mpfs-icicle-kit-es

 Download the official SD card image released by Microchip and prepare it for
 QEMU usage:

 .. code-block:: bash

   $ wget ftp://ftpsoc.microsemi.com/outgoing/core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic.gz
   $ gunzip core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic.gz
   $ qemu-img resize core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic 4G

 Then we can boot the machine by:

 .. code-block:: bash

   $ qemu-system-riscv64 -M microchip-icicle-kit -smp 5 \
       -bios path/to/hss.bin -sd path/to/sdcard.img \
       -nic user,model=cadence_gem \
       -nic tap,ifname=tap,model=cadence_gem,script=no \
       -display none -serial stdio \
       -chardev socket,id=serial1,path=serial1.sock,server=on,wait=on \
       -serial chardev:serial1

 With above command line, current terminal session will be used for the first
 serial port. Open another terminal window, and use ``minicom`` to connect the
 second serial port.

 .. code-block:: bash

   $ minicom -D unix\#serial1.sock

 HSS output is on the first serial port (stdio) and U-Boot outputs on the
 second serial port. U-Boot will automatically load the Linux kernel from
 the SD card image.

 Direct Kernel Boot
 ------------------

 Sometimes we just want to test booting a new kernel, and transforming the
 kernel image to the format required by the HSS bootflow is tedious. We can
 use '-kernel' for direct kernel booting just like other RISC-V machines do.

 In this mode, the OpenSBI fw_dynamic BIOS image for 'generic' platform is
 used to boot an S-mode payload like U-Boot or OS kernel directly.

 For example, the following commands show building a U-Boot image from U-Boot
 mainline v2021.07 for the Microchip Icicle Kit board:

 .. code-block:: bash

   $ export CROSS_COMPILE=riscv64-linux-
   $ make microchip_mpfs_icicle_defconfig

 Then we can boot the machine by:

 .. code-block:: bash

   $ qemu-system-riscv64 -M microchip-icicle-kit -smp 5 -m 2G \
       -sd path/to/sdcard.img \
       -nic user,model=cadence_gem \
       -nic tap,ifname=tap,model=cadence_gem,script=no \
       -display none -serial stdio \
       -kernel path/to/u-boot/build/dir/u-boot.bin \
       -dtb path/to/u-boot/build/dir/u-boot.dtb

 CAVEATS:

 * Check the "stdout-path" property in the /chosen node in the DTB to determine
   which serial port is used for the serial console, e.g.: if the console is set
   to the second serial port, change to use "-serial null -serial stdio".
 * The default U-Boot configuration uses CONFIG_OF_SEPARATE hence the ELF image
   ``u-boot`` cannot be passed to "-kernel" as it does not contain the DTB hence
   ``u-boot.bin`` has to be used which does contain one. To use the ELF image,
   we need to change to CONFIG_OF_EMBED or CONFIG_OF_PRIOR_STAGE.

 .. _HSS: https://github.com/polarfire-soc/hart-software-services
	Microchip PolarFire SoC Icicle Kit (``microchip-icicle-kit``)
	=============================================================

	Microchip PolarFire SoC Icicle Kit integrates a PolarFire SoC, with one
	SiFive's E51 plus four U54 cores and many on-chip peripherals and an FPGA.

	For more details about Microchip PolarFire SoC, please see:
	https://www.microsemi.com/product-directory/soc-fpgas/5498-polarfire-soc-fpga

	The Icicle Kit board information can be found here:
	https://www.microsemi.com/existing-parts/parts/152514

	Supported devices
	-----------------

	The ``microchip-icicle-kit`` machine supports the following devices:

	* 1 E51 core
	* 4 U54 cores
	* Core Level Interruptor (CLINT)
	* Platform-Level Interrupt Controller (PLIC)
	* L2 Loosely Integrated Memory (L2-LIM)
	* DDR memory controller
	* 5 MMUARTs
	* 1 DMA controller
	* 2 GEM Ethernet controllers
	* 1 SDHC storage controller

	Boot options
	------------

	The ``microchip-icicle-kit`` machine can start using the standard -bios
	functionality for loading its BIOS image, aka Hart Software Services (HSS_).
	HSS loads the second stage bootloader U-Boot from an SD card. Then a kernel
	can be loaded from U-Boot. It also supports direct kernel booting via the
	-kernel option along with the device tree blob via -dtb. When direct kernel
	boot is used, the OpenSBI fw_dynamic BIOS image is used to boot a payload
	like U-Boot or OS kernel directly.

	The user provided DTB should have the following requirements:

	* The /cpus node should contain at least one subnode for E51 and the number
	of subnodes should match QEMU's ``-smp`` option
	* The /memory reg size should match QEMU’s selected ram_size via ``-m``
	* Should contain a node for the CLINT device with a compatible string
	"riscv,clint0"

	QEMU follows below truth table to select which payload to execute:

	===== ========== ========== =======
	-bios -kernel -dtb payload
	===== ========== ========== =======
	N N don't care HSS
	Y don't care don't care HSS
	N Y Y kernel
	===== ========== ========== =======

	The memory is set to 1537 MiB by default which is the minimum required high
	memory size by HSS. A sanity check on ram size is performed in the machine
	init routine to prompt user to increase the RAM size to > 1537 MiB when less
	than 1537 MiB ram is detected.

	Running HSS
	-----------

	HSS 2020.12 release is tested at the time of writing. To build an HSS image
	that can be booted by the ``microchip-icicle-kit`` machine, type the following
	in the HSS source tree:

	.. code-block:: bash

	$ export CROSS_COMPILE=riscv64-linux-
	$ cp boards/mpfs-icicle-kit-es/def_config .config
	$ make BOARD=mpfs-icicle-kit-es

	Download the official SD card image released by Microchip and prepare it for
	QEMU usage:

	.. code-block:: bash

	$ wget ftp://ftpsoc.microsemi.com/outgoing/core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic.gz
	$ gunzip core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic.gz
	$ qemu-img resize core-image-minimal-dev-icicle-kit-es-sd-20201009141623.rootfs.wic 4G

	Then we can boot the machine by:

	.. code-block:: bash

	$ qemu-system-riscv64 -M microchip-icicle-kit -smp 5 \
	-bios path/to/hss.bin -sd path/to/sdcard.img \
	-nic user,model=cadence_gem \
	-nic tap,ifname=tap,model=cadence_gem,script=no \
	-display none -serial stdio \
	-chardev socket,id=serial1,path=serial1.sock,server=on,wait=on \
	-serial chardev:serial1

	With above command line, current terminal session will be used for the first
	serial port. Open another terminal window, and use ``minicom`` to connect the
	second serial port.

	.. code-block:: bash

	$ minicom -D unix\#serial1.sock

	HSS output is on the first serial port (stdio) and U-Boot outputs on the
	second serial port. U-Boot will automatically load the Linux kernel from
	the SD card image.

	Direct Kernel Boot
	------------------

	Sometimes we just want to test booting a new kernel, and transforming the
	kernel image to the format required by the HSS bootflow is tedious. We can
	use '-kernel' for direct kernel booting just like other RISC-V machines do.

	In this mode, the OpenSBI fw_dynamic BIOS image for 'generic' platform is
	used to boot an S-mode payload like U-Boot or OS kernel directly.

	For example, the following commands show building a U-Boot image from U-Boot
	mainline v2021.07 for the Microchip Icicle Kit board:

	.. code-block:: bash

	$ export CROSS_COMPILE=riscv64-linux-
	$ make microchip_mpfs_icicle_defconfig

	Then we can boot the machine by:

	.. code-block:: bash

	$ qemu-system-riscv64 -M microchip-icicle-kit -smp 5 -m 2G \
	-sd path/to/sdcard.img \
	-nic user,model=cadence_gem \
	-nic tap,ifname=tap,model=cadence_gem,script=no \
	-display none -serial stdio \
	-kernel path/to/u-boot/build/dir/u-boot.bin \
	-dtb path/to/u-boot/build/dir/u-boot.dtb

	CAVEATS:

	* Check the "stdout-path" property in the /chosen node in the DTB to determine
	which serial port is used for the serial console, e.g.: if the console is set
	to the second serial port, change to use "-serial null -serial stdio".
	* The default U-Boot configuration uses CONFIG_OF_SEPARATE hence the ELF image
	``u-boot`` cannot be passed to "-kernel" as it does not contain the DTB hence
	``u-boot.bin`` has to be used which does contain one. To use the ELF image,
	we need to change to CONFIG_OF_EMBED or CONFIG_OF_PRIOR_STAGE.

	.. _HSS: https://github.com/polarfire-soc/hart-software-services