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android / platform / external / crosvm / 6e8f33aa0a902aca5e56773d10c1cff7bf989acd / . / aarch64 / src / fdt.rs
blob: 4ae191d34ee7610b19b73707f696485cb861e39a [file] [log] [blame]
// Copyright 2018 The Chromium OS Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
use std::fs::File;
use std::io::Read;
use arch::fdt::{Error, FdtWriter, Result};
use arch::SERIAL_ADDR;
use devices::{PciAddress, PciInterruptPin};
use hypervisor::PsciVersion;
use vm_memory::{GuestAddress, GuestMemory};
// This is the start of DRAM in the physical address space.
use crate::AARCH64_PHYS_MEM_START;
// These are GIC address-space location constants.
use crate::AARCH64_GIC_CPUI_BASE;
use crate::AARCH64_GIC_CPUI_SIZE;
use crate::AARCH64_GIC_DIST_BASE;
use crate::AARCH64_GIC_DIST_SIZE;
use crate::AARCH64_GIC_REDIST_SIZE;
// These are RTC related constants
use crate::AARCH64_RTC_ADDR;
use crate::AARCH64_RTC_IRQ;
use crate::AARCH64_RTC_SIZE;
use devices::pl030::PL030_AMBA_ID;
// These are serial device related constants.
use crate::AARCH64_SERIAL_1_3_IRQ;
use crate::AARCH64_SERIAL_2_4_IRQ;
use crate::AARCH64_SERIAL_SIZE;
use crate::AARCH64_SERIAL_SPEED;
// These are related to guest virtio devices.
use crate::AARCH64_MMIO_BASE;
use crate::AARCH64_MMIO_SIZE;
use crate::AARCH64_PCI_CFG_BASE;
use crate::AARCH64_PCI_CFG_SIZE;
use crate::AARCH64_PMU_IRQ;
// This is an arbitrary number to specify the node for the GIC.
// If we had a more complex interrupt architecture, then we'd need an enum for
// these.
const PHANDLE_GIC: u32 = 1;
// These are specified by the Linux GIC bindings
const GIC_FDT_IRQ_NUM_CELLS: u32 = 3;
const GIC_FDT_IRQ_TYPE_SPI: u32 = 0;
const GIC_FDT_IRQ_TYPE_PPI: u32 = 1;
const GIC_FDT_IRQ_PPI_CPU_SHIFT: u32 = 8;
const GIC_FDT_IRQ_PPI_CPU_MASK: u32 = 0xff << GIC_FDT_IRQ_PPI_CPU_SHIFT;
const IRQ_TYPE_EDGE_RISING: u32 = 0x00000001;
const IRQ_TYPE_LEVEL_HIGH: u32 = 0x00000004;
const IRQ_TYPE_LEVEL_LOW: u32 = 0x00000008;
fn create_memory_node(fdt: &mut FdtWriter, guest_mem: &GuestMemory) -> Result<()> {
let mem_size = guest_mem.memory_size();
let mem_reg_prop = [AARCH64_PHYS_MEM_START, mem_size];
let memory_node = fdt.begin_node("memory")?;
fdt.property_string("device_type", "memory")?;
fdt.property_array_u64("reg", &mem_reg_prop)?;
fdt.end_node(memory_node)?;
Ok(())
}
fn create_cpu_nodes(fdt: &mut FdtWriter, num_cpus: u32) -> Result<()> {
let cpus_node = fdt.begin_node("cpus")?;
fdt.property_u32("#address-cells", 0x1)?;
fdt.property_u32("#size-cells", 0x0)?;
for cpu_id in 0..num_cpus {
let cpu_name = format!("cpu@{:x}", cpu_id);
let cpu_node = fdt.begin_node(&cpu_name)?;
fdt.property_string("device_type", "cpu")?;
fdt.property_string("compatible", "arm,arm-v8")?;
if num_cpus > 1 {
fdt.property_string("enable-method", "psci")?;
}
fdt.property_u32("reg", cpu_id)?;
fdt.end_node(cpu_node)?;
}
fdt.end_node(cpus_node)?;
Ok(())
}
fn create_gic_node(fdt: &mut FdtWriter, is_gicv3: bool, num_cpus: u64) -> Result<()> {
let mut gic_reg_prop = [AARCH64_GIC_DIST_BASE, AARCH64_GIC_DIST_SIZE, 0, 0];
let intc_node = fdt.begin_node("intc")?;
if is_gicv3 {
fdt.property_string("compatible", "arm,gic-v3")?;
gic_reg_prop[2] = AARCH64_GIC_DIST_BASE - (AARCH64_GIC_REDIST_SIZE * num_cpus);
gic_reg_prop[3] = AARCH64_GIC_REDIST_SIZE * num_cpus;
} else {
fdt.property_string("compatible", "arm,cortex-a15-gic")?;
gic_reg_prop[2] = AARCH64_GIC_CPUI_BASE;
gic_reg_prop[3] = AARCH64_GIC_CPUI_SIZE;
}
fdt.property_u32("#interrupt-cells", GIC_FDT_IRQ_NUM_CELLS)?;
fdt.property_null("interrupt-controller")?;
fdt.property_array_u64("reg", &gic_reg_prop)?;
fdt.property_u32("phandle", PHANDLE_GIC)?;
fdt.property_u32("#address-cells", 2)?;
fdt.property_u32("#size-cells", 2)?;
fdt.end_node(intc_node)?;
Ok(())
}
fn create_timer_node(fdt: &mut FdtWriter, num_cpus: u32) -> Result<()> {
// These are fixed interrupt numbers for the timer device.
let irqs = [13, 14, 11, 10];
let compatible = "arm,armv8-timer";
let cpu_mask: u32 =
(((1 << num_cpus) - 1) << GIC_FDT_IRQ_PPI_CPU_SHIFT) & GIC_FDT_IRQ_PPI_CPU_MASK;
let mut timer_reg_cells = Vec::new();
for &irq in &irqs {
timer_reg_cells.push(GIC_FDT_IRQ_TYPE_PPI);
timer_reg_cells.push(irq);
timer_reg_cells.push(cpu_mask | IRQ_TYPE_LEVEL_LOW);
}
let timer_node = fdt.begin_node("timer")?;
fdt.property_string("compatible", compatible)?;
fdt.property_array_u32("interrupts", &timer_reg_cells)?;
fdt.property_null("always-on")?;
fdt.end_node(timer_node)?;
Ok(())
}
fn create_pmu_node(fdt: &mut FdtWriter, num_cpus: u32) -> Result<()> {
let compatible = "arm,armv8-pmuv3";
let cpu_mask: u32 =
(((1 << num_cpus) - 1) << GIC_FDT_IRQ_PPI_CPU_SHIFT) & GIC_FDT_IRQ_PPI_CPU_MASK;
let irq = [
GIC_FDT_IRQ_TYPE_PPI,
AARCH64_PMU_IRQ,
cpu_mask | IRQ_TYPE_LEVEL_HIGH,
];
let pmu_node = fdt.begin_node("pmu")?;
fdt.property_string("compatible", compatible)?;
fdt.property_array_u32("interrupts", &irq)?;
fdt.end_node(pmu_node)?;
Ok(())
}
fn create_serial_node(fdt: &mut FdtWriter, addr: u64, irq: u32) -> Result<()> {
let serial_reg_prop = [addr, AARCH64_SERIAL_SIZE];
let irq = [GIC_FDT_IRQ_TYPE_SPI, irq, IRQ_TYPE_EDGE_RISING];
let serial_node = fdt.begin_node(&format!("U6_16550A@{:x}", addr))?;
fdt.property_string("compatible", "ns16550a")?;
fdt.property_array_u64("reg", &serial_reg_prop)?;
fdt.property_u32("clock-frequency", AARCH64_SERIAL_SPEED)?;
fdt.property_array_u32("interrupts", &irq)?;
fdt.end_node(serial_node)?;
Ok(())
}
fn create_serial_nodes(fdt: &mut FdtWriter) -> Result<()> {
// Note that SERIAL_ADDR contains the I/O port addresses conventionally used
// for serial ports on x86. This uses the same addresses (but on the MMIO bus)
// to simplify the shared serial code.
create_serial_node(fdt, SERIAL_ADDR[0], AARCH64_SERIAL_1_3_IRQ)?;
create_serial_node(fdt, SERIAL_ADDR[1], AARCH64_SERIAL_2_4_IRQ)?;
create_serial_node(fdt, SERIAL_ADDR[2], AARCH64_SERIAL_1_3_IRQ)?;
create_serial_node(fdt, SERIAL_ADDR[3], AARCH64_SERIAL_2_4_IRQ)?;
Ok(())
}
fn create_psci_node(fdt: &mut FdtWriter, version: &PsciVersion) -> Result<()> {
let mut compatible = vec![format!("arm,psci-{}.{}", version.major, version.minor)];
if version.major == 1 {
// Put `psci-0.2` as well because PSCI 1.0 is compatible with PSCI 0.2.
compatible.push(format!("arm,psci-0.2"))
};
let psci_node = fdt.begin_node("psci")?;
fdt.property_string_list("compatible", compatible)?;
// Only support aarch64 guest
fdt.property_string("method", "hvc")?;
fdt.end_node(psci_node)?;
Ok(())
}
fn create_chosen_node(
fdt: &mut FdtWriter,
cmdline: &str,
initrd: Option<(GuestAddress, usize)>,
) -> Result<()> {
let chosen_node = fdt.begin_node("chosen")?;
fdt.property_u32("linux,pci-probe-only", 1)?;
fdt.property_string("bootargs", cmdline)?;
// Used by android bootloader for boot console output
fdt.property_string("stdout-path", &format!("/U6_16550A@{:x}", SERIAL_ADDR[0]))?;
let mut random_file = File::open("/dev/urandom").map_err(Error::FdtIoError)?;
let mut kaslr_seed_bytes = [0u8; 8];
random_file
.read_exact(&mut kaslr_seed_bytes)
.map_err(Error::FdtIoError)?;
let kaslr_seed = u64::from_le_bytes(kaslr_seed_bytes);
fdt.property_u64("kaslr-seed", kaslr_seed)?;
let mut rng_seed_bytes = [0u8; 256];
random_file
.read_exact(&mut rng_seed_bytes)
.map_err(Error::FdtIoError)?;
fdt.property("rng-seed", &rng_seed_bytes)?;
if let Some((initrd_addr, initrd_size)) = initrd {
let initrd_start = initrd_addr.offset() as u32;
let initrd_end = initrd_start + initrd_size as u32;
fdt.property_u32("linux,initrd-start", initrd_start)?;
fdt.property_u32("linux,initrd-end", initrd_end)?;
}
fdt.end_node(chosen_node)?;
Ok(())
}
fn create_pci_nodes(
fdt: &mut FdtWriter,
pci_irqs: Vec<(PciAddress, u32, PciInterruptPin)>,
pci_device_base: u64,
pci_device_size: u64,
) -> Result<()> {
// Add devicetree nodes describing a PCI generic host controller.
// See Documentation/devicetree/bindings/pci/host-generic-pci.txt in the kernel
// and "PCI Bus Binding to IEEE Std 1275-1994".
let ranges = [
// mmio addresses
0x3000000, // (ss = 11: 64-bit memory space)
(AARCH64_MMIO_BASE >> 32) as u32, // PCI address
AARCH64_MMIO_BASE as u32,
(AARCH64_MMIO_BASE >> 32) as u32, // CPU address
AARCH64_MMIO_BASE as u32,
(AARCH64_MMIO_SIZE >> 32) as u32, // size
AARCH64_MMIO_SIZE as u32,
// device addresses
0x3000000, // (ss = 11: 64-bit memory space)
(pci_device_base >> 32) as u32, // PCI address
pci_device_base as u32,
(pci_device_base >> 32) as u32, // CPU address
pci_device_base as u32,
(pci_device_size >> 32) as u32, // size
pci_device_size as u32,
];
let bus_range = [0, 0]; // Only bus 0
let reg = [AARCH64_PCI_CFG_BASE, AARCH64_PCI_CFG_SIZE];
let mut interrupts: Vec<u32> = Vec::new();
let mut masks: Vec<u32> = Vec::new();
for (address, irq_num, irq_pin) in pci_irqs.iter() {
// PCI_DEVICE(3)
interrupts.push(address.to_config_address(0));
interrupts.push(0);
interrupts.push(0);
// INT#(1)
interrupts.push(irq_pin.to_mask() + 1);
// CONTROLLER(PHANDLE)
interrupts.push(PHANDLE_GIC);
interrupts.push(0);
interrupts.push(0);
// CONTROLLER_DATA(3)
interrupts.push(GIC_FDT_IRQ_TYPE_SPI);
interrupts.push(*irq_num);
interrupts.push(IRQ_TYPE_LEVEL_HIGH);
// PCI_DEVICE(3)
masks.push(0xf800); // bits 11..15 (device)
masks.push(0);
masks.push(0);
// INT#(1)
masks.push(0x7); // allow INTA#-INTD# (1 | 2 | 3 | 4)
}
let pci_node = fdt.begin_node("pci")?;
fdt.property_string("compatible", "pci-host-cam-generic")?;
fdt.property_string("device_type", "pci")?;
fdt.property_array_u32("ranges", &ranges)?;
fdt.property_array_u32("bus-range", &bus_range)?;
fdt.property_u32("#address-cells", 3)?;
fdt.property_u32("#size-cells", 2)?;
fdt.property_array_u64("reg", &reg)?;
fdt.property_u32("#interrupt-cells", 1)?;
fdt.property_array_u32("interrupt-map", &interrupts)?;
fdt.property_array_u32("interrupt-map-mask", &masks)?;
fdt.property_null("dma-coherent")?;
fdt.end_node(pci_node)?;
Ok(())
}
fn create_rtc_node(fdt: &mut FdtWriter) -> Result<()> {
// the kernel driver for pl030 really really wants a clock node
// associated with an AMBA device or it will fail to probe, so we
// need to make up a clock node to associate with the pl030 rtc
// node and an associated handle with a unique phandle value.
const CLK_PHANDLE: u32 = 24;
let clock_node = fdt.begin_node("pclk@3M")?;
fdt.property_u32("#clock-cells", 0)?;
fdt.property_string("compatible", "fixed-clock")?;
fdt.property_u32("clock-frequency", 3141592)?;
fdt.property_u32("phandle", CLK_PHANDLE)?;
fdt.end_node(clock_node)?;
let rtc_name = format!("rtc@{:x}", AARCH64_RTC_ADDR);
let reg = [AARCH64_RTC_ADDR, AARCH64_RTC_SIZE];
let irq = [GIC_FDT_IRQ_TYPE_SPI, AARCH64_RTC_IRQ, IRQ_TYPE_LEVEL_HIGH];
let rtc_node = fdt.begin_node(&rtc_name)?;
fdt.property_string("compatible", "arm,primecell")?;
fdt.property_u32("arm,primecell-periphid", PL030_AMBA_ID)?;
fdt.property_array_u64("reg", &reg)?;
fdt.property_array_u32("interrupts", &irq)?;
fdt.property_u32("clocks", CLK_PHANDLE)?;
fdt.property_string("clock-names", "apb_pclk")?;
fdt.end_node(rtc_node)?;
Ok(())
}
/// Creates a flattened device tree containing all of the parameters for the
/// kernel and loads it into the guest memory at the specified offset.
///
/// # Arguments
///
/// * `fdt_max_size` - The amount of space reserved for the device tree
/// * `guest_mem` - The guest memory object
/// * `pci_irqs` - List of PCI device address to PCI interrupt number and pin mappings
/// * `num_cpus` - Number of virtual CPUs the guest will have
/// * `fdt_load_offset` - The offset into physical memory for the device tree
/// * `pci_device_base` - The offset into physical memory for PCI device memory
/// * `pci_device_size` - The size of PCI device memory
/// * `cmdline` - The kernel commandline
/// * `initrd` - An optional tuple of initrd guest physical address and size
/// * `android_fstab` - An optional file holding Android fstab entries
/// * `is_gicv3` - True if gicv3, false if v2
/// * `psci_version` - the current PSCI version
pub fn create_fdt(
fdt_max_size: usize,
guest_mem: &GuestMemory,
pci_irqs: Vec<(PciAddress, u32, PciInterruptPin)>,
num_cpus: u32,
fdt_load_offset: u64,
pci_device_base: u64,
pci_device_size: u64,
cmdline: &str,
initrd: Option<(GuestAddress, usize)>,
android_fstab: Option<File>,
is_gicv3: bool,
use_pmu: bool,
psci_version: PsciVersion,
) -> Result<()> {
let mut fdt = FdtWriter::new(&[]);
// The whole thing is put into one giant node with some top level properties
let root_node = fdt.begin_node("")?;
fdt.property_u32("interrupt-parent", PHANDLE_GIC)?;
fdt.property_string("compatible", "linux,dummy-virt")?;
fdt.property_u32("#address-cells", 0x2)?;
fdt.property_u32("#size-cells", 0x2)?;
if let Some(android_fstab) = android_fstab {
arch::android::create_android_fdt(&mut fdt, android_fstab)?;
}
create_chosen_node(&mut fdt, cmdline, initrd)?;
create_memory_node(&mut fdt, guest_mem)?;
create_cpu_nodes(&mut fdt, num_cpus)?;
create_gic_node(&mut fdt, is_gicv3, num_cpus as u64)?;
create_timer_node(&mut fdt, num_cpus)?;
if use_pmu {
create_pmu_node(&mut fdt, num_cpus)?;
}
create_serial_nodes(&mut fdt)?;
create_psci_node(&mut fdt, &psci_version)?;
create_pci_nodes(&mut fdt, pci_irqs, pci_device_base, pci_device_size)?;
create_rtc_node(&mut fdt)?;
// End giant node
fdt.end_node(root_node)?;
let fdt_final = fdt.finish(fdt_max_size)?;
let fdt_address = GuestAddress(AARCH64_PHYS_MEM_START + fdt_load_offset);
let written = guest_mem
.write_at_addr(fdt_final.as_slice(), fdt_address)
.map_err(|_| Error::FdtGuestMemoryWriteError)?;
if written < fdt_max_size {
return Err(Error::FdtGuestMemoryWriteError);
}
Ok(())
}