1SiFive HiFive Unleashed (``sifive_u``) 2====================================== 3 4SiFive HiFive Unleashed Development Board is the ultimate RISC-V development 5board featuring the Freedom U540 multi-core RISC-V processor. 6 7Supported devices 8----------------- 9 10The ``sifive_u`` machine supports the following devices: 11 12* 1 E51 / E31 core 13* Up to 4 U54 / U34 cores 14* Core Local Interruptor (CLINT) 15* Platform-Level Interrupt Controller (PLIC) 16* Power, Reset, Clock, Interrupt (PRCI) 17* L2 Loosely Integrated Memory (L2-LIM) 18* DDR memory controller 19* 2 UARTs 20* 1 GEM Ethernet controller 21* 1 GPIO controller 22* 1 One-Time Programmable (OTP) memory with stored serial number 23* 1 DMA controller 24* 2 QSPI controllers 25* 1 ISSI 25WP256 flash 26* 1 SD card in SPI mode 27* PWM0 and PWM1 28 29Please note the real world HiFive Unleashed board has a fixed configuration of 301 E51 core and 4 U54 core combination and the RISC-V core boots in 64-bit mode. 31With QEMU, one can create a machine with 1 E51 core and up to 4 U54 cores. It 32is also possible to create a 32-bit variant with the same peripherals except 33that the RISC-V cores are replaced by the 32-bit ones (E31 and U34), to help 34testing of 32-bit guest software. 35 36Hardware configuration information 37---------------------------------- 38 39The ``sifive_u`` machine automatically generates a device tree blob ("dtb") 40which it passes to the guest, if there is no ``-dtb`` option. This provides 41information about the addresses, interrupt lines and other configuration of 42the various devices in the system. Guest software should discover the devices 43that are present in the generated DTB instead of using a DTB for the real 44hardware, as some of the devices are not modeled by QEMU and trying to access 45these devices may cause unexpected behavior. 46 47If users want to provide their own DTB, they can use the ``-dtb`` option. 48These DTBs should have the following requirements: 49 50* The /cpus node should contain at least one subnode for E51 and the number 51 of subnodes should match QEMU's ``-smp`` option 52* The /memory reg size should match QEMU’s selected ram_size via ``-m`` 53* Should contain a node for the CLINT device with a compatible string 54 "riscv,clint0" if using with OpenSBI BIOS images 55 56Boot options 57------------ 58 59The ``sifive_u`` machine can start using the standard -kernel functionality 60for loading a Linux kernel, a VxWorks kernel, a modified U-Boot bootloader 61(S-mode) or ELF executable with the default OpenSBI firmware image as the 62-bios. It also supports booting the unmodified U-Boot bootloader using the 63standard -bios functionality. 64 65Machine-specific options 66------------------------ 67 68The following machine-specific options are supported: 69 70- serial=nnn 71 72 The board serial number. When not given, the default serial number 1 is used. 73 74 SiFive reserves the first 1 KiB of the 16 KiB OTP memory for internal use. 75 The current usage is only used to store the serial number of the board at 76 offset 0xfc. U-Boot reads the serial number from the OTP memory, and uses 77 it to generate a unique MAC address to be programmed to the on-chip GEM 78 Ethernet controller. When multiple QEMU ``sifive_u`` machines are created 79 and connected to the same subnet, they all have the same MAC address hence 80 it creates an unusable network. In such scenario, user should give different 81 values to serial= when creating different ``sifive_u`` machines. 82 83- start-in-flash 84 85 When given, QEMU's ROM codes jump to QSPI memory-mapped flash directly. 86 Otherwise QEMU will jump to DRAM or L2LIM depending on the msel= value. 87 When not given, it defaults to direct DRAM booting. 88 89- msel=[6|11] 90 91 Mode Select (MSEL[3:0]) pins value, used to control where to boot from. 92 93 The FU540 SoC supports booting from several sources, which are controlled 94 using the Mode Select pins on the chip. Typically, the boot process runs 95 through several stages before it begins execution of user-provided programs. 96 These stages typically include the following: 97 98 1. Zeroth Stage Boot Loader (ZSBL), which is contained in an on-chip mask 99 ROM and provided by QEMU. Note QEMU implemented ROM codes are not the 100 same as what is programmed in the hardware. The QEMU one is a simplified 101 version, but it provides the same functionality as the hardware. 102 2. First Stage Boot Loader (FSBL), which brings up PLLs and DDR memory. 103 This is U-Boot SPL. 104 3. Second Stage Boot Loader (SSBL), which further initializes additional 105 peripherals as needed. This is U-Boot proper combined with an OpenSBI 106 fw_dynamic firmware image. 107 108 msel=6 means FSBL and SSBL are both on the QSPI flash. msel=11 means FSBL 109 and SSBL are both on the SD card. 110 111Running Linux kernel 112-------------------- 113 114Linux mainline v5.10 release is tested at the time of writing. To build a 115Linux mainline kernel that can be booted by the ``sifive_u`` machine in 11664-bit mode, simply configure the kernel using the defconfig configuration: 117 118.. code-block:: bash 119 120 $ export ARCH=riscv 121 $ export CROSS_COMPILE=riscv64-linux- 122 $ make defconfig 123 $ make 124 125To boot the newly built Linux kernel in QEMU with the ``sifive_u`` machine: 126 127.. code-block:: bash 128 129 $ qemu-system-riscv64 -M sifive_u -smp 5 -m 2G \ 130 -display none -serial stdio \ 131 -kernel arch/riscv/boot/Image \ 132 -initrd /path/to/rootfs.ext4 \ 133 -append "root=/dev/ram" 134 135Alternatively, we can use a custom DTB to boot the machine by inserting a CLINT 136node in fu540-c000.dtsi in the Linux kernel, 137 138.. code-block:: none 139 140 clint: clint@2000000 { 141 compatible = "riscv,clint0"; 142 interrupts-extended = <&cpu0_intc 3 &cpu0_intc 7 143 &cpu1_intc 3 &cpu1_intc 7 144 &cpu2_intc 3 &cpu2_intc 7 145 &cpu3_intc 3 &cpu3_intc 7 146 &cpu4_intc 3 &cpu4_intc 7>; 147 reg = <0x00 0x2000000 0x00 0x10000>; 148 }; 149 150with the following command line options: 151 152.. code-block:: bash 153 154 $ qemu-system-riscv64 -M sifive_u -smp 5 -m 8G \ 155 -display none -serial stdio \ 156 -kernel arch/riscv/boot/Image \ 157 -dtb arch/riscv/boot/dts/sifive/hifive-unleashed-a00.dtb \ 158 -initrd /path/to/rootfs.ext4 \ 159 -append "root=/dev/ram" 160 161To build a Linux mainline kernel that can be booted by the ``sifive_u`` machine 162in 32-bit mode, use the rv32_defconfig configuration. A patch is required to 163fix the 32-bit boot issue for Linux kernel v5.10. 164 165.. code-block:: bash 166 167 $ export ARCH=riscv 168 $ export CROSS_COMPILE=riscv64-linux- 169 $ curl https://patchwork.kernel.org/project/linux-riscv/patch/20201219001356.2887782-1-atish.patra@wdc.com/mbox/ > riscv.patch 170 $ git am riscv.patch 171 $ make rv32_defconfig 172 $ make 173 174Replace ``qemu-system-riscv64`` with ``qemu-system-riscv32`` in the command 175line above to boot the 32-bit Linux kernel. A rootfs image containing 32-bit 176applications shall be used in order for kernel to boot to user space. 177 178Running VxWorks kernel 179---------------------- 180 181VxWorks 7 SR0650 release is tested at the time of writing. To build a 64-bit 182VxWorks mainline kernel that can be booted by the ``sifive_u`` machine, simply 183create a VxWorks source build project based on the sifive_generic BSP, and a 184VxWorks image project to generate the bootable VxWorks image, by following the 185BSP documentation instructions. 186 187A pre-built 64-bit VxWorks 7 image for HiFive Unleashed board is available as 188part of the VxWorks SDK for testing as well. Instructions to download the SDK: 189 190.. code-block:: bash 191 192 $ wget https://labs.windriver.com/downloads/wrsdk-vxworks7-sifive-hifive-1.01.tar.bz2 193 $ tar xvf wrsdk-vxworks7-sifive-hifive-1.01.tar.bz2 194 $ ls bsps/sifive_generic_1_0_0_0/uboot/uVxWorks 195 196To boot the VxWorks kernel in QEMU with the ``sifive_u`` machine, use: 197 198.. code-block:: bash 199 200 $ qemu-system-riscv64 -M sifive_u -smp 5 -m 2G \ 201 -display none -serial stdio \ 202 -nic tap,ifname=tap0,script=no,downscript=no \ 203 -kernel /path/to/vxWorks \ 204 -append "gem(0,0)host:vxWorks h=192.168.200.1 e=192.168.200.2:ffffff00 u=target pw=vxTarget f=0x01" 205 206It is also possible to test 32-bit VxWorks on the ``sifive_u`` machine. Create 207a 32-bit project to build the 32-bit VxWorks image, and use exact the same 208command line options with ``qemu-system-riscv32``. 209 210Running U-Boot 211-------------- 212 213U-Boot mainline v2021.07 release is tested at the time of writing. To build a 214U-Boot mainline bootloader that can be booted by the ``sifive_u`` machine, use 215the sifive_unleashed_defconfig with similar commands as described above for 216Linux: 217 218.. code-block:: bash 219 220 $ export CROSS_COMPILE=riscv64-linux- 221 $ export OPENSBI=/path/to/opensbi-riscv64-generic-fw_dynamic.bin 222 $ make sifive_unleashed_defconfig 223 224You will get spl/u-boot-spl.bin and u-boot.itb file in the build tree. 225 226To start U-Boot using the ``sifive_u`` machine, prepare an SPI flash image, or 227SD card image that is properly partitioned and populated with correct contents. 228genimage_ can be used to generate these images. 229 230A sample configuration file for a 128 MiB SD card image is: 231 232.. code-block:: bash 233 234 $ cat genimage_sdcard.cfg 235 image sdcard.img { 236 size = 128M 237 238 hdimage { 239 gpt = true 240 } 241 242 partition u-boot-spl { 243 image = "u-boot-spl.bin" 244 offset = 17K 245 partition-type-uuid = 5B193300-FC78-40CD-8002-E86C45580B47 246 } 247 248 partition u-boot { 249 image = "u-boot.itb" 250 offset = 1041K 251 partition-type-uuid = 2E54B353-1271-4842-806F-E436D6AF6985 252 } 253 } 254 255SPI flash image has slightly different partition offsets, and the size has to 256be 32 MiB to match the ISSI 25WP256 flash on the real board: 257 258.. code-block:: bash 259 260 $ cat genimage_spi-nor.cfg 261 image spi-nor.img { 262 size = 32M 263 264 hdimage { 265 gpt = true 266 } 267 268 partition u-boot-spl { 269 image = "u-boot-spl.bin" 270 offset = 20K 271 partition-type-uuid = 5B193300-FC78-40CD-8002-E86C45580B47 272 } 273 274 partition u-boot { 275 image = "u-boot.itb" 276 offset = 1044K 277 partition-type-uuid = 2E54B353-1271-4842-806F-E436D6AF6985 278 } 279 } 280 281Assume U-Boot binaries are put in the same directory as the config file, 282we can generate the image by: 283 284.. code-block:: bash 285 286 $ genimage --config genimage_<boot_src>.cfg --inputpath . 287 288Boot U-Boot from SD card, by specifying msel=11 and pass the SD card image 289to QEMU ``sifive_u`` machine: 290 291.. code-block:: bash 292 293 $ qemu-system-riscv64 -M sifive_u,msel=11 -smp 5 -m 8G \ 294 -display none -serial stdio \ 295 -bios /path/to/u-boot-spl.bin \ 296 -drive file=/path/to/sdcard.img,if=sd 297 298Changing msel= value to 6, allows booting U-Boot from the SPI flash: 299 300.. code-block:: bash 301 302 $ qemu-system-riscv64 -M sifive_u,msel=6 -smp 5 -m 8G \ 303 -display none -serial stdio \ 304 -bios /path/to/u-boot-spl.bin \ 305 -drive file=/path/to/spi-nor.img,if=mtd 306 307Note when testing U-Boot, QEMU automatically generated device tree blob is 308not used because U-Boot itself embeds device tree blobs for U-Boot SPL and 309U-Boot proper. Hence the number of cores and size of memory have to match 310the real hardware, ie: 5 cores (-smp 5) and 8 GiB memory (-m 8G). 311 312Above use case is to run upstream U-Boot for the SiFive HiFive Unleashed 313board on QEMU ``sifive_u`` machine out of the box. This allows users to 314develop and test the recommended RISC-V boot flow with a real world use 315case: ZSBL (in QEMU) loads U-Boot SPL from SD card or SPI flash to L2LIM, 316then U-Boot SPL loads the combined payload image of OpenSBI fw_dynamic 317firmware and U-Boot proper. 318 319However sometimes we want to have a quick test of booting U-Boot on QEMU 320without the needs of preparing the SPI flash or SD card images, an alternate 321way can be used, which is to create a U-Boot S-mode image by modifying the 322configuration of U-Boot: 323 324.. code-block:: bash 325 326 $ export CROSS_COMPILE=riscv64-linux- 327 $ make sifive_unleashed_defconfig 328 $ make menuconfig 329 330then manually select the following configuration: 331 332 * Device Tree Control ---> Provider of DTB for DT Control ---> Prior Stage bootloader DTB 333 334and unselect the following configuration: 335 336 * Library routines ---> Allow access to binman information in the device tree 337 338This changes U-Boot to use the QEMU generated device tree blob, and bypass 339running the U-Boot SPL stage. 340 341Boot the 64-bit U-Boot S-mode image directly: 342 343.. code-block:: bash 344 345 $ qemu-system-riscv64 -M sifive_u -smp 5 -m 2G \ 346 -display none -serial stdio \ 347 -kernel /path/to/u-boot.bin 348 349It's possible to create a 32-bit U-Boot S-mode image as well. 350 351.. code-block:: bash 352 353 $ export CROSS_COMPILE=riscv64-linux- 354 $ make sifive_unleashed_defconfig 355 $ make menuconfig 356 357then manually update the following configuration in U-Boot: 358 359 * Device Tree Control ---> Provider of DTB for DT Control ---> Prior Stage bootloader DTB 360 * RISC-V architecture ---> Base ISA ---> RV32I 361 * Boot options ---> Boot images ---> Text Base ---> 0x80400000 362 363and unselect the following configuration: 364 365 * Library routines ---> Allow access to binman information in the device tree 366 367Use the same command line options to boot the 32-bit U-Boot S-mode image: 368 369.. code-block:: bash 370 371 $ qemu-system-riscv32 -M sifive_u -smp 5 -m 2G \ 372 -display none -serial stdio \ 373 -kernel /path/to/u-boot.bin 374 375.. _genimage: https://github.com/pengutronix/genimage 376