58f9cf7c04
Signed-off-by: Peter Bee <bijunda1@xiaomi.com>
406 lines
16 KiB
Plaintext
406 lines
16 KiB
Plaintext
README.txt
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==========
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This board configuration will use QEMU to emulate generic ARM64 v8-A series
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hardware platform and provides support for these devices:
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- GICv2 and GICv3 interrupt controllers
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- ARM Generic Timer
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- PL011 UART controller
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Contents
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========
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- Getting Started
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- Status
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- Platform Features
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- Debugging with QEMU
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- FPU Support and Performance
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- SMP Support
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- References
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Getting Started
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===============
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1. Compile Toolchain
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1.1 Host environment
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GNU/Linux: Ubuntu 18.04 or greater
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1.2 Download and Install
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$ wget https://developer.arm.com/-/media/Files/downloads/gnu/11.2-2022.02/binrel/gcc-arm-11.2-2022.02-x86_64-aarch64-none-elf.tar.xz
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$ xz -d gcc-arm-11.2-2022.02-x86_64-aarch64-none-elf.tar.xz
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$ tar xf gcc-arm-11.2-2022.02-x86_64-aarch64-none-elf.tar
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Put gcc-arm-11.2-2022.02-x86_64-aarch64-none-elf/bin/ to your host PATH environment variable, like:
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$ export PATH=$PATH:/opt/software/arm/linaro-toolchain/gcc-arm-11.2-2022.02-x86_64-aarch64-none-elf/bin
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check the toolchain:
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$ aarch64-none-elf-gcc -v
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2. Install QEMU
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In Ubuntu 18.04(or greater), install qemu:
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$ sudo apt-get install qemu-system-arm qemu-efi-aarch64 qemu-utils
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And make sure install is properly:
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$ qemu-system-aarch64 --help
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3. Configuring and running
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3.1 Single Core (GICv3)
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Configuring NuttX and compile:
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$ ./tools/configure.sh -l qemu-armv8a:nsh
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$ make
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Running with qemu
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$ qemu-system-aarch64 -cpu cortex-a53 -nographic \
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-machine virt,virtualization=on,gic-version=3 \
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-net none -chardev stdio,id=con,mux=on -serial chardev:con \
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-mon chardev=con,mode=readline -kernel ./nuttx
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3.1.1 Single Core with virtio network, block, rng, serial driver (GICv3)
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Configuring NuttX and compile:
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$ ./tools/configure.sh -l qemu-armv8a:netnsh
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$ make
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$ dd if=/dev/zero of=./mydisk-1gb.img bs=1M count=1024
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Running with qemu
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$ qemu-system-aarch64 -cpu cortex-a53 -nographic \
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-machine virt,virtualization=on,gic-version=3 \
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-chardev stdio,id=con,mux=on -serial chardev:con \
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-global virtio-mmio.force-legacy=false \
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-device virtio-serial-device,bus=virtio-mmio-bus.0 \
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-chardev socket,telnet=on,host=127.0.0.1,port=3450,server=on,wait=off,id=foo \
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-device virtconsole,chardev=foo \
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-device virtio-rng-device,bus=virtio-mmio-bus.1 \
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-netdev user,id=u1,hostfwd=tcp:127.0.0.1:10023-10.0.2.15:23,hostfwd=tcp:127.0.0.1:15001-10.0.2.15:5001 \
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-device virtio-net-device,netdev=u1,bus=virtio-mmio-bus.2 \
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-drive file=./mydisk-1gb.img,if=none,format=raw,id=hd \
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-device virtio-blk-device,bus=virtio-mmio-bus.3,drive=hd \
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-mon chardev=con,mode=readline -kernel ./nuttx
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3.1.2 Single Core with virtio gpu driver (GICv3)
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Configuring NuttX and compile:
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$ ./tools/configure.sh qemu-armv8a:fb
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$ make -j
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Running with qemu
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$ qemu-system-aarch64 -cpu cortex-a53 \
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-machine virt,virtualization=on,gic-version=3 \
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-chardev stdio,id=con,mux=on -serial chardev:con \
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-global virtio-mmio.force-legacy=false \
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-device virtio-gpu-device,xres=640,yres=480,bus=virtio-mmio-bus.0 \
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-mon chardev=con,mode=readline -kernel ./nuttx
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NuttShell (NSH) NuttX-10.4.0
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nsh> fb
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3.2 SMP (GICv3)
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Configuring NuttX and compile:
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$ ./tools/configure.sh -l qemu-armv8a:nsh_smp
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$ make
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Running with qemu
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$ qemu-system-aarch64 -cpu cortex-a53 -smp 4 -nographic \
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-machine virt,virtualization=on,gic-version=3 \
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-net none -chardev stdio,id=con,mux=on -serial chardev:con \
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-mon chardev=con,mode=readline -kernel ./nuttx
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3.2.1 SMP (GICv3)
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Configuring NuttX and compile:
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$ ./tools/configure.sh -l qemu-armv8a:netnsh_smp
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$ make
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Running with qemu
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$ qemu-system-aarch64 -cpu cortex-a53 -smp 4 -nographic \
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-machine virt,virtualization=on,gic-version=3 \
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-chardev stdio,id=con,mux=on -serial chardev:con \
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-global virtio-mmio.force-legacy=false \
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-netdev user,id=u1,hostfwd=tcp:127.0.0.1:10023-10.0.2.15:23,hostfwd=tcp:127.0.0.1:15001-10.0.2.15:5001 \
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-device virtio-net-device,netdev=u1,bus=virtio-mmio-bus.0 \
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-mon chardev=con,mode=readline -kernel ./nuttx
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3.3 Single Core (GICv2)
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Configuring NuttX and compile:
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$ ./tools/configure.sh -l qemu-armv8a:nsh_gicv2
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$ make
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Running with qemu
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$ qemu-system-aarch64 -cpu cortex-a53 -nographic \
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-machine virt,virtualization=on,gic-version=2 \
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-net none -chardev stdio,id=con,mux=on -serial chardev:con \
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-mon chardev=con,mode=readline -kernel ./nuttx
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Note:
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1. Make sure the aarch64-none-elf toolchain install PATH has been added to environment variable
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2. To quit QEMU, type Ctrl + X
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3. Nuttx default core number is 4, and Changing CONFIG_SMP_NCPUS > 4 and setting qemu command
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option -smp will boot more core. For qemu, core limit is 32.
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3.4 SMP + Networking with hypervisor (GICv2)
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Configuring NuttX and compile:
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$ ./tools/configure.sh -l qemu-armv8a:netnsh_smp_hv
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$ make
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Running with qemu + kvm on raspi3b+ (ubuntu server 20.04)
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$ qemu-system-aarch64 -nographic \
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-machine virt -cpu host -smp 4 -accel kvm \
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-chardev stdio,id=con,mux=on -serial chardev:con \
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-global virtio-mmio.force-legacy=false \
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-drive file=./mydisk-1gb.img,if=none,format=raw,id=hd -device virtio-blk-device,drive=hd \
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-netdev user,id=u1,hostfwd=tcp:127.0.0.1:10023-10.0.2.15:23,hostfwd=tcp:127.0.0.1:15001-10.0.2.15:5001 \
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-device virtio-net-device,netdev=u1,bus=virtio-mmio-bus.0 \
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-mon chardev=con,mode=readline -kernel ./nuttx
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Running with qemu + hvf on M1/MacBook Pro (macOS 12.6.1)
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$ qemu-system-aarch64 -nographic \
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-machine virt -cpu host -smp 4 -accel hvf \
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-chardev stdio,id=con,mux=on -serial chardev:con \
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-global virtio-mmio.force-legacy=false \
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-drive file=./mydisk-1gb.img,if=none,format=raw,id=hd -device virtio-blk-device,drive=hd \
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-netdev user,id=u1,hostfwd=tcp:127.0.0.1:10023-10.0.2.15:23,hostfwd=tcp:127.0.0.1:15001-10.0.2.15:5001 \
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-device virtio-net-device,netdev=u1,bus=virtio-mmio-bus.0 \
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-mon chardev=con,mode=readline -kernel ./nuttx
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Status
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======
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2022-11-18:
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1. Added support for GICv2.
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2. Added board configuration for nsh_gicv2.
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2022-10-13:
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1. Renamed the board configuration name from qemu-a53 to qemu-v8a.
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2. Added the configurations for Cortex-A57 and Cortex-A72.
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2022-07-01:
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1. It's very stranger to see that signal testing of ostest is PASSED at Physical Ubuntu PC
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rather than an Ubuntu at VMWare. For Physical Ubuntu PC, I have run the ostest
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for 10 times at least but never see the crash again, but it's almost crashed every time
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running the ostest at Virtual Ubuntu in VMWare
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I check the fail point. It's seem at signal routine to access another CPU's task context reg
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will get a NULL pointer, but I watch the task context with GDB, everything is OK.
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So maybe this is a SMP cache synchronize issue? But I have done cache synchronize
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operation at thread switch and how to explain why the crash not happening at
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Physical Ubuntu PC?
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So maybe this is a qemu issue at VMWare. I am planning to run
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the arm64 to real hardware platform like IMX8 and will check the issue again
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2022-06-12:
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1. SMP is support at QEMU. Add psci interface, armv8 cache operation(data cache)
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and smccc support. The system can run into nsh shell, SMP test is PASSED, but
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ostest crash at signal testing
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2022-05-22:
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Arm64 support version for NuttX is Ready, These Features supported:
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1.Cotex-a53 single core support: With the supporting of GICv3,
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Arch timer, PL101 UART, The system can run into nsh shell.
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Running ostest seem PASSED.
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2.qemu-a53 board configuration support: qemu-a53 board can configuring
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and compiling, And running with qemu-system-aarch64
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at Ubuntu 18.04.
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3.FPU support for armv8-a: FPU context switching in NEON/floating-point
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TRAP was supported. FPU registers saving at vfork and independent
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FPU context for signal routine was considered but more testing
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needs to be do.
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Platform Features
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=================
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The following hardware features are supported:
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+--------------+------------+----------------------+
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| Interface | Controller | Driver/Component |
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+==============+============+======================+
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| GIC | on-chip | interrupt controller |
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+--------------+------------+----------------------+
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| PL011 UART | on-chip | serial port |
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+--------------+------------+----------------------+
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| ARM TIMER | on-chip | system clock |
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+--------------+------------+----------------------+
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The kernel currently does not support other hardware features on this
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qemu platform.
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Debugging with QEMU
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===================
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The nuttx ELF image can be debugged with QEMU.
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1. To debug the nuttx (ELF) with symbols, make sure the following change have
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applied to defconfig.
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+CONFIG_DEBUG_SYMBOLS=y
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2. Run QEMU(at shell terminal 1)
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Single Core
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$ qemu-system-aarch64 -cpu cortex-a53 -nographic -machine virt,virtualization=on,gic-version=3 \
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-net none -chardev stdio,id=con,mux=on -serial chardev:con -mon chardev=con,mode=readline \
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-kernel ./nuttx -S -s
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SMP
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$ qemu-system-aarch64 -cpu cortex-a53 -smp 4 -nographic -machine virt,virtualization=on,gic-version=3 \
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-net none -chardev stdio,id=con,mux=on -serial chardev:con -mon chardev=con,mode=readline \
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-kernel ./nuttx -S -s
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3. Run gdb with TUI, connect to QEMU, load nuttx and continue (at shell terminal 2)
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$ aarch64-none-elf-gdb -tui --eval-command='target remote localhost:1234' nuttx
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(gdb) set debug aarch64
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(gdb) c
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Continuing.
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^C
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Program received signal SIGINT, Interrupt.
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arch_cpu_idle () at common/arm64_cpu_idle.S:37
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(gdb)
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(gdb) where
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#0 arch_cpu_idle () at common/arm64_cpu_idle.S:37
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#1 0x00000000402823ec in nx_start () at init/nx_start.c:742
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#2 0x0000000040280148 in arm64_boot_primary_c_routine () at common/arm64_boot.c:184
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#3 0x00000000402a5bf8 in switch_el () at common/arm64_head.S:201
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(gdb)
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SMP Case
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Thread 1 received signal SIGINT, Interrupt.
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arch_cpu_idle () at common/arm64_cpu_idle.S:37
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(gdb) info threads
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Id Target Id Frame
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* 1 Thread 1 (CPU#0 [halted ]) arch_cpu_idle () at common/arm64_cpu_idle.S:37
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2 Thread 2 (CPU#1 [halted ]) arch_cpu_idle () at common/arm64_cpu_idle.S:37
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3 Thread 3 (CPU#2 [halted ]) arch_cpu_idle () at common/arm64_cpu_idle.S:37
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4 Thread 4 (CPU#3 [halted ]) arch_cpu_idle () at common/arm64_cpu_idle.S:37
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(gdb)
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Note:
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1. it will make your debugging more easier in source level if you setting
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CONFIG_DEBUG_FULLOPT=n. but there is a risk of stack overflow when the
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option is disabled. Just enlarging your stack size will avoid the
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issue (eg. enlarging CONFIG_DEFAULT_TASK_STACKSIZE)
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2. TODO: ARMv8-A Supporting for tools/nuttx-gdbinit
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FPU Support and Performance
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===========================
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I was using FPU trap to handle FPU context switch. For threads accessing
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the FPU (FPU instructions or registers), a trap will happen at this thread,
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the FPU context will be saved/restore for the thread at the trap handler.
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It will improve performance for thread switch since it's not to save/restore
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the FPU context (almost 512 bytes) at the thread switch anymore. But some issue
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need to be considered:
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1. Floating point argument passing issue
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In many cases, the FPU trap is triggered by va_start() that copies
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the content of FP registers used for floating point argument passing
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into the va_list object in case there were actual float arguments from
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the caller.
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adding -mgeneral-regs-only option will make compiler not use the FPU
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register, we can use the following patch to syslog:
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diff --git a/libs/libc/syslog/Make.defs b/libs/libc/syslog/Make.defs
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index c58fb45512..acac6febaa
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--- a/libs/libc/syslog/Make.defs
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+++ b/libs/libc/syslog/Make.defs
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@@ -26,3 +26,4 @@ CSRCS += lib_syslog.c lib_setlogmask.c
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DEPPATH += --dep-path syslog
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VPATH += :syslog
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+syslog/lib_syslog.c_CFLAGS += -mgeneral-regs-only
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I cannot commit the patch for NuttX mainline because it's very special case
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since ostest is using syslog for lots of information printing. but this is
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a clue for FPU performance analysis. va_list object is using for many C code to
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handle argument passing, but if it's not passing floating point argument indeed.
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Add the option to your code maybe increase FPU performance
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2. memset/memcpy issue
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For improve performance, the memset/memcpy implement for libc will
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use the neon/fpu instruction/register. The FPU trap is also triggered
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in this case.
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we can trace this issue with Procfs:
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nsh> cat /proc/arm64fpu
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CPU0: save: 7 restore: 8 switch: 62 exedepth: 0
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nsh>
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after ostest
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nsh> cat /proc/arm64fpu
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CPU0: save: 1329 restore: 2262 switch: 4613 exedepth: 0
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nsh>
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Note:
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save: the counts of save for task FPU context
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restore: the counts of restore for task FPU context
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switch: the counts of task switch
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2. FPU trap at IRQ handler
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it's probably need to handle FPU trap at IRQ routine. Exception_depth is
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handling for this case, it will inc/dec at enter/leave exception. If the
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exception_depth > 1, that means an exception occurring when another exception
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is executing, the present implement is to switch FPU context to idle thread,
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it will handle most case for calling printf-like routine at IRQ routine.
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But in fact, this case will make uncertainty interrupt processing time sine
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it's uncertainty for trap exception handling. It would be best to add
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"-mgeneral-regs-only" option to compile the IRQ code avoiding accessing FP
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register.
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if it's necessarily for the exception routine to use FPU, calling function to
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save/restore FPU context directly maybe become a solution. Linux kernel introduce
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kernel_neon_begin/kernel_neon_end function for this case. Similar function will
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be add to NuttX if this issue need to be handle.
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3. More reading
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for Linux kernel, please reference:
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- https://www.kernel.org/doc/html/latest/arm/kernel_mode_neon.html
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SMP Support
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===========
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1. Booting
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Primary core call sequence
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arm64_start
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->arm64_boot_primary_c_routine
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->arm64_chip_boot
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->set init TBBR and Enable MMU
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->nx_start
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->OS component initialize
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->Initialize GIC: GICD and Primary core GICR
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->nx_smp_start
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for every CPU core
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->up_cpu_start
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->arm64_start_cpu(call PCSI to boot CPU)
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->waiting for every core to boot
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->nx_bringup
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Secondary Core call sequence
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arm64_start
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->arm64_boot_secondary_c_routine
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->Enable MMU
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->Initialize GIC: Secondary core GICR
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->Notify Primary core booting is Ready
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->nx_idle_trampoline
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2. interrupt
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SGI
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SGI_CPU_PAUSE: for core pause request, for every core
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PPI
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ARM_ARCH_TIMER_IRQ: timer interrupt, handle by primary Core
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SPI
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CONFIG_QEMU_UART_IRQ: serial driver interrupt, handle by primary Core
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3. Timer
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The origin design for ARMv8-A timer is assigned private timer to
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every PE(CPU core), the ARM_ARCH_TIMER_IRQ is a PPI so it's
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should be enabled at every core.
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But for NuttX, it's design only for primary core to handle timer
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interrupt and call nxsched_process_timer at timer tick mode.
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So we need only enable timer for primary core
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IMX6 use GPT which is a SPI rather than generic timer to handle
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timer interrupt
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References
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===========
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1. (ID050815) ARM® Cortex®-A Series - Programmer’s Guide for ARMv8-A
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2. (ID020222) Arm® Architecture Reference Manual - for A profile architecture
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3. (ARM062-948681440-3280) Armv8-A Instruction Set Architecture
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4. AArch64 Exception and Interrupt Handling
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5. AArch64 Programmer's Guides Generic Timer
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6. Arm Generic Interrupt Controller v3 and v4 Overview
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7. Arm® Generic Interrupt Controller Architecture Specification GIC architecture version 3 and version 4
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8. (DEN0022D.b) Arm Power State Coordination Interface Platform Design Document
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