doc/board/emulation/qemu-riscv.rst - u-boot - Git at Google

 .. SPDX-License-Identifier: GPL-2.0+
 .. Copyright (C) 2018, Bin Meng <bmeng.cn@gmail.com>

 QEMU RISC-V
 ===========

 QEMU for RISC-V supports a special 'virt' machine and 'spike' machine designed
 for emulation and virtualization purposes. This document describes how to run
 U-Boot under it. Both 32-bit and 64-bit targets are supported, running in
 either machine or supervisor mode.

 The QEMU virt machine models a generic RISC-V virtual machine with support for
 the VirtIO standard networking and block storage devices. It has CLINT, PLIC,
 16550A UART devices in addition to VirtIO and it also uses device-tree to pass
 configuration information to guest software. It implements the latest RISC-V
 privileged architecture.

 See :doc:`../../develop/devicetree/dt_qemu` for information on how to see
 the devicetree actually generated by QEMU.

 The QEMU spike machine models a minimalistic RISC-V virtual machine with
 only CLINT and HTIF devices. It also uses device-tree to pass configuration
 information to guest software and implements the latest RISC-V privileged
 architecture.

 Building U-Boot
 ---------------
 Set the CROSS_COMPILE environment variable as usual, and run:

 - For 32-bit RISC-V::

     make qemu-riscv32_defconfig
     make

 - For 64-bit RISC-V::

     make qemu-riscv64_defconfig
     make

 This will compile U-Boot for machine mode. To build supervisor mode binaries,
 use the configurations qemu-riscv32_smode_defconfig and
 qemu-riscv64_smode_defconfig instead. Note that U-Boot running in supervisor
 mode requires a supervisor binary interface (SBI), such as RISC-V OpenSBI.

 Running U-Boot
 --------------
 The minimal QEMU command line to get U-Boot up and running is:

 - For 32-bit RISC-V virt machine::

     qemu-system-riscv32 -nographic -machine virt -bios u-boot.bin

 - For 64-bit RISC-V virt machine::

     qemu-system-riscv64 -nographic -machine virt -bios u-boot.bin

 - For 64-bit RISC-V spike machine::

     qemu-system-riscv64 -nographic -machine spike -bios u-boot.bin

 The commands above create targets with 128MiB memory by default.
 A freely configurable amount of RAM can be created via the '-m'
 parameter. For example, '-m 2G' creates 2GiB memory for the target,
 and the memory node in the embedded DTB created by QEMU reflects
 the new setting.

 For instructions on how to run U-Boot in supervisor mode on QEMU
 with OpenSBI, see the documentation available with OpenSBI:
 https://github.com/riscv/opensbi/blob/master/docs/platform/qemu_virt.md
 https://github.com/riscv/opensbi/blob/master/docs/platform/spike.md

 These have been tested in QEMU 5.0.0.

 Running U-Boot SPL
 ------------------
 In the default SPL configuration, U-Boot SPL starts in machine mode. U-Boot
 proper and OpenSBI (FW_DYNAMIC firmware) are bundled as FIT image and made
 available to U-Boot SPL. Both are then loaded by U-Boot SPL and the location
 of U-Boot proper is passed to OpenSBI. After initialization, U-Boot proper is
 started in supervisor mode by OpenSBI.

 OpenSBI must be compiled before compiling U-Boot. Version 0.4 and higher is
 supported by U-Boot. Clone the OpenSBI repository and run the following command.

 .. code-block:: console

     git clone https://github.com/riscv/opensbi.git
     cd opensbi
     make PLATFORM=generic

 See the OpenSBI documentation for full details:
 https://github.com/riscv/opensbi/blob/master/docs/platform/qemu_virt.md
 https://github.com/riscv/opensbi/blob/master/docs/platform/spike.md

 To make the FW_DYNAMIC binary (build/platform/generic/firmware/fw_dynamic.bin)
 available to U-Boot, either copy it into the U-Boot root directory or specify
 its location with the OPENSBI environment variable. Afterwards, compile U-Boot
 with the following commands.

 - For 32-bit RISC-V::

     make qemu-riscv32_spl_defconfig
     make

 - For 64-bit RISC-V::

     make qemu-riscv64_spl_defconfig
     make

 The minimal QEMU commands to run U-Boot SPL in both 32-bit and 64-bit
 configurations are:

 - For 32-bit RISC-V virt machine::

     qemu-system-riscv32 -nographic -machine virt -bios spl/u-boot-spl.bin \
     -device loader,file=u-boot.itb,addr=0x80200000

 - For 64-bit RISC-V virt machine::

     qemu-system-riscv64 -nographic -machine virt -bios spl/u-boot-spl.bin \
     -device loader,file=u-boot.itb,addr=0x80200000

 - For 64-bit RISC-V spike machine::

     qemu-system-riscv64 -nographic -machine spike -bios spl/u-boot-spl.bin \
     -device loader,file=u-boot.itb,addr=0x80200000

 An attached disk can be emulated in RISC-V virt machine by adding::

     -device ich9-ahci,id=ahci \
     -drive if=none,file=riscv64.img,format=raw,id=mydisk \
     -device ide-hd,drive=mydisk,bus=ahci.0

 or alternatively attach an emulated UFS::

     -device ufs,id=ufs0 \
     -drive if=none,file=test.img,format=raw,id=lun0 \
     -device ufs-lu,drive=lun0,bus=ufs0

 You will have to run 'scsi scan' to use them.

 A video console can be emulated in RISC-V virt machine by removing "-nographic"
 and adding::

     -serial stdio -device VGA

 In addition, a usb keyboard can be attached to an emulated xHCI controller in
 RISC-V virt machine as an option of input devices by adding::

     -device qemu-xhci,id=xhci -device usb-kbd,bus=xhci.0

 Running with KVM
 ----------------

 Running with QEMU using KVM requires an S-mode U-Boot binary as created by
 qemu-riscv64_smode_defconfig.

 Provide the U-Boot S-mode ELF image as *-kernel* parameter and do not add a
 *-bios* parameter, e.g.

 .. code-block:: bash

     qemu-system-riscv64 -accel kvm -nographic -machine virt -kernel u-boot

 Debug UART
 ----------

 The following settings provide a debug UART for the virt machine::

     CONFIG_DEBUG_UART=y
     CONFIG_DEBUG_UART_NS16550=y
     CONFIG_DEBUG_UART_BASE=0x10000000
     CONFIG_DEBUG_UART_CLOCK=3686400
	.. SPDX-License-Identifier: GPL-2.0+
	.. Copyright (C) 2018, Bin Meng <bmeng.cn@gmail.com>

	QEMU RISC-V
	===========

	QEMU for RISC-V supports a special 'virt' machine and 'spike' machine designed
	for emulation and virtualization purposes. This document describes how to run
	U-Boot under it. Both 32-bit and 64-bit targets are supported, running in
	either machine or supervisor mode.

	The QEMU virt machine models a generic RISC-V virtual machine with support for
	the VirtIO standard networking and block storage devices. It has CLINT, PLIC,
	16550A UART devices in addition to VirtIO and it also uses device-tree to pass
	configuration information to guest software. It implements the latest RISC-V
	privileged architecture.

	See :doc:`../../develop/devicetree/dt_qemu` for information on how to see
	the devicetree actually generated by QEMU.

	The QEMU spike machine models a minimalistic RISC-V virtual machine with
	only CLINT and HTIF devices. It also uses device-tree to pass configuration
	information to guest software and implements the latest RISC-V privileged
	architecture.

	Building U-Boot
	---------------
	Set the CROSS_COMPILE environment variable as usual, and run:

	- For 32-bit RISC-V::

	make qemu-riscv32_defconfig
	make

	- For 64-bit RISC-V::

	make qemu-riscv64_defconfig
	make

	This will compile U-Boot for machine mode. To build supervisor mode binaries,
	use the configurations qemu-riscv32_smode_defconfig and
	qemu-riscv64_smode_defconfig instead. Note that U-Boot running in supervisor
	mode requires a supervisor binary interface (SBI), such as RISC-V OpenSBI.

	Running U-Boot
	--------------
	The minimal QEMU command line to get U-Boot up and running is:

	- For 32-bit RISC-V virt machine::

	qemu-system-riscv32 -nographic -machine virt -bios u-boot.bin

	- For 64-bit RISC-V virt machine::

	qemu-system-riscv64 -nographic -machine virt -bios u-boot.bin

	- For 64-bit RISC-V spike machine::

	qemu-system-riscv64 -nographic -machine spike -bios u-boot.bin

	The commands above create targets with 128MiB memory by default.
	A freely configurable amount of RAM can be created via the '-m'
	parameter. For example, '-m 2G' creates 2GiB memory for the target,
	and the memory node in the embedded DTB created by QEMU reflects
	the new setting.

	For instructions on how to run U-Boot in supervisor mode on QEMU
	with OpenSBI, see the documentation available with OpenSBI:
	https://github.com/riscv/opensbi/blob/master/docs/platform/qemu_virt.md
	https://github.com/riscv/opensbi/blob/master/docs/platform/spike.md

	These have been tested in QEMU 5.0.0.

	Running U-Boot SPL
	------------------
	In the default SPL configuration, U-Boot SPL starts in machine mode. U-Boot
	proper and OpenSBI (FW_DYNAMIC firmware) are bundled as FIT image and made
	available to U-Boot SPL. Both are then loaded by U-Boot SPL and the location
	of U-Boot proper is passed to OpenSBI. After initialization, U-Boot proper is
	started in supervisor mode by OpenSBI.

	OpenSBI must be compiled before compiling U-Boot. Version 0.4 and higher is
	supported by U-Boot. Clone the OpenSBI repository and run the following command.

	.. code-block:: console

	git clone https://github.com/riscv/opensbi.git
	cd opensbi
	make PLATFORM=generic

	See the OpenSBI documentation for full details:
	https://github.com/riscv/opensbi/blob/master/docs/platform/qemu_virt.md
	https://github.com/riscv/opensbi/blob/master/docs/platform/spike.md

	To make the FW_DYNAMIC binary (build/platform/generic/firmware/fw_dynamic.bin)
	available to U-Boot, either copy it into the U-Boot root directory or specify
	its location with the OPENSBI environment variable. Afterwards, compile U-Boot
	with the following commands.

	- For 32-bit RISC-V::

	make qemu-riscv32_spl_defconfig
	make

	- For 64-bit RISC-V::

	make qemu-riscv64_spl_defconfig
	make

	The minimal QEMU commands to run U-Boot SPL in both 32-bit and 64-bit
	configurations are:

	- For 32-bit RISC-V virt machine::

	qemu-system-riscv32 -nographic -machine virt -bios spl/u-boot-spl.bin \
	-device loader,file=u-boot.itb,addr=0x80200000

	- For 64-bit RISC-V virt machine::

	qemu-system-riscv64 -nographic -machine virt -bios spl/u-boot-spl.bin \
	-device loader,file=u-boot.itb,addr=0x80200000

	- For 64-bit RISC-V spike machine::

	qemu-system-riscv64 -nographic -machine spike -bios spl/u-boot-spl.bin \
	-device loader,file=u-boot.itb,addr=0x80200000

	An attached disk can be emulated in RISC-V virt machine by adding::

	-device ich9-ahci,id=ahci \
	-drive if=none,file=riscv64.img,format=raw,id=mydisk \
	-device ide-hd,drive=mydisk,bus=ahci.0

	or alternatively attach an emulated UFS::

	-device ufs,id=ufs0 \
	-drive if=none,file=test.img,format=raw,id=lun0 \
	-device ufs-lu,drive=lun0,bus=ufs0

	You will have to run 'scsi scan' to use them.

	A video console can be emulated in RISC-V virt machine by removing "-nographic"
	and adding::

	-serial stdio -device VGA

	In addition, a usb keyboard can be attached to an emulated xHCI controller in
	RISC-V virt machine as an option of input devices by adding::

	-device qemu-xhci,id=xhci -device usb-kbd,bus=xhci.0

	Running with KVM
	----------------

	Running with QEMU using KVM requires an S-mode U-Boot binary as created by
	qemu-riscv64_smode_defconfig.

	Provide the U-Boot S-mode ELF image as -kernel parameter and do not add a
	-bios parameter, e.g.

	.. code-block:: bash

	qemu-system-riscv64 -accel kvm -nographic -machine virt -kernel u-boot

	Debug UART
	----------

	The following settings provide a debug UART for the virt machine::

	CONFIG_DEBUG_UART=y
	CONFIG_DEBUG_UART_NS16550=y
	CONFIG_DEBUG_UART_BASE=0x10000000
	CONFIG_DEBUG_UART_CLOCK=3686400