// Copyright 2020 Arm Limited (or its affiliates). All rights reserved. // Copyright 2019 Amazon.com, Inc. or its affiliates. All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 /// Module for the flattened device tree. pub mod fdt; /// Module for the global interrupt controller configuration. pub mod gic; mod gicv2; mod gicv3; mod gicv3_its; /// Layout for this aarch64 system. pub mod layout; /// Logic for configuring aarch64 registers. pub mod regs; pub use self::fdt::DeviceInfoForFDT; use crate::DeviceType; use crate::RegionType; use std::collections::HashMap; use std::ffi::CStr; use std::fmt::Debug; use std::sync::Arc; use vm_memory::{ Address, GuestAddress, GuestAddressSpace, GuestMemory, GuestMemoryAtomic, GuestMemoryMmap, GuestUsize, }; /// Errors thrown while configuring aarch64 system. #[derive(Debug)] pub enum Error { /// Failed to create a FDT. SetupFDT(fdt::Error), /// Failed to create a GIC. SetupGIC(gic::Error), /// Failed to compute the initrd address. InitrdAddress, /// Error configuring the general purpose registers REGSConfiguration(regs::Error), /// Error fetching prefered target VcpuArmPreferredTarget(hypervisor::HypervisorVmError), /// Error doing Vcpu Init on Arm. VcpuArmInit(hypervisor::HypervisorCpuError), } impl From for super::Error { fn from(e: Error) -> super::Error { super::Error::AArch64Setup(e) } } #[derive(Debug, Copy, Clone)] /// Specifies the entry point address where the guest must start /// executing code. pub struct EntryPoint { /// Address in guest memory where the guest must start execution pub entry_addr: GuestAddress, } /// Configure the specified VCPU, and return its MPIDR. pub fn configure_vcpu( fd: &Arc, id: u8, vm: &Arc, kernel_entry_point: Option, vm_memory: &GuestMemoryAtomic, ) -> super::Result { let mut kvi: kvm_bindings::kvm_vcpu_init = kvm_bindings::kvm_vcpu_init::default(); // This reads back the kernel's preferred target type. vm.get_preferred_target(&mut kvi) .map_err(Error::VcpuArmPreferredTarget)?; // We already checked that the capability is supported. kvi.features[0] |= 1 << kvm_bindings::KVM_ARM_VCPU_PSCI_0_2; // Non-boot cpus are powered off initially. if id > 0 { kvi.features[0] |= 1 << kvm_bindings::KVM_ARM_VCPU_POWER_OFF; } fd.vcpu_init(&kvi).map_err(Error::VcpuArmInit)?; if let Some(kernel_entry_point) = kernel_entry_point { regs::setup_regs( fd, id, kernel_entry_point.entry_addr.raw_value(), &vm_memory.memory(), ) .map_err(Error::REGSConfiguration)?; } let mpidr = regs::read_mpidr(fd).map_err(Error::REGSConfiguration)?; Ok(mpidr) } pub fn arch_memory_regions(size: GuestUsize) -> Vec<(GuestAddress, usize, RegionType)> { let mut regions = Vec::new(); // 0 ~ 256 MiB: Reserved regions.push(( GuestAddress(0), layout::MEM_32BIT_DEVICES_START.0 as usize, RegionType::Reserved, )); // 256 MiB ~ 1 G: MMIO space regions.push(( layout::MEM_32BIT_DEVICES_START, layout::MEM_32BIT_DEVICES_SIZE as usize, RegionType::SubRegion, )); // 1G ~ 2G: reserved. The leading 256M for PCIe MMCONFIG space regions.push(( layout::PCI_MMCONFIG_START, (layout::RAM_64BIT_START - layout::PCI_MMCONFIG_START.0) as usize, RegionType::Reserved, )); regions.push(( GuestAddress(layout::RAM_64BIT_START), size as usize, RegionType::Ram, )); regions } /// Configures the system and should be called once per vm before starting vcpu threads. /// /// # Arguments /// /// * `guest_mem` - The memory to be used by the guest. /// * `num_cpus` - Number of virtual CPUs the guest will have. #[allow(clippy::too_many_arguments)] #[allow(unused_variables)] pub fn configure_system( vm: &Arc, guest_mem: &GuestMemoryMmap, cmdline_cstring: &CStr, vcpu_count: u64, vcpu_mpidr: Vec, device_info: &HashMap<(DeviceType, String), T>, initrd: &Option, ) -> super::Result<()> { let gic_device = gic::create_gic(vm, vcpu_count).map_err(Error::SetupGIC)?; let dtb = fdt::create_fdt( guest_mem, cmdline_cstring, vcpu_mpidr, device_info, &gic_device, initrd, ) .map_err(Error::SetupFDT)?; Ok(()) } /// Returns the memory address where the kernel could be loaded. pub fn get_kernel_start() -> u64 { layout::RAM_64BIT_START } // Auxiliary function to get the address where the device tree blob is loaded. fn get_fdt_addr(mem: &GuestMemoryMmap) -> u64 { // If the memory allocated is smaller than the size allocated for the FDT, // we return the start of the DRAM so that // we allow the code to try and load the FDT. if let Some(addr) = mem.last_addr().checked_sub(layout::FDT_MAX_SIZE as u64 - 1) { if mem.address_in_range(addr) { return addr.raw_value(); } } layout::RAM_64BIT_START } pub fn get_host_cpu_phys_bits() -> u8 { // The value returned here is used to determine the physical address space size // for a VM (IPA size). // In recent kernel versions, the maxium IPA size supported by the host can be // known by querying cap KVM_CAP_ARM_VM_IPA_SIZE. And the IPA size for a // guest can be configured smaller. // But in Cloud-Hypervisor we simply use the maxium value for the VM. // Reference https://lwn.net/Articles/766767/. // // The correct way to query KVM_CAP_ARM_VM_IPA_SIZE is via rust-vmm/kvm-ioctls, // which wraps all IOCTL's and provides easy interface to user hypervisors. // For now the cap hasn't been supported. A separate patch will be submitted to // rust-vmm to add it. // So a hardcoded value is used here as a temporary solution. // It will be replace once rust-vmm/kvm-ioctls is ready. // 40 } #[cfg(test)] mod tests { use super::*; #[test] fn test_arch_memory_regions_dram() { let regions = arch_memory_regions((1usize << 32) as u64); //4GB assert_eq!(4, regions.len()); assert_eq!(GuestAddress(layout::RAM_64BIT_START), regions[3].0); assert_eq!(1usize << 32, regions[3].1); assert_eq!(RegionType::Ram, regions[3].2); } #[test] fn test_get_fdt_addr() { let mut regions = Vec::new(); regions.push(( GuestAddress(layout::RAM_64BIT_START), (layout::FDT_MAX_SIZE - 0x1000) as usize, )); let mem = GuestMemoryMmap::from_ranges(®ions).expect("Cannot initialize memory"); assert_eq!(get_fdt_addr(&mem), layout::RAM_64BIT_START); regions.clear(); regions.push(( GuestAddress(layout::RAM_64BIT_START), (layout::FDT_MAX_SIZE) as usize, )); let mem = GuestMemoryMmap::from_ranges(®ions).expect("Cannot initialize memory"); assert_eq!(get_fdt_addr(&mem), layout::RAM_64BIT_START); regions.clear(); regions.push(( GuestAddress(layout::RAM_64BIT_START), (layout::FDT_MAX_SIZE + 0x1000) as usize, )); let mem = GuestMemoryMmap::from_ranges(®ions).expect("Cannot initialize memory"); assert_eq!(get_fdt_addr(&mem), 0x1000 + layout::RAM_64BIT_START); regions.clear(); } }