pvmfw/src/main.rs - android_packages_modules_Virtualization - Gitiles

 // Copyright 2022, The Android Open Source Project
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 //! pVM firmware.

 #![no_main]
 #![no_std]

 extern crate alloc;

 mod bootargs;
 mod config;
 mod crypto;
 mod dice;
 mod entry;
 mod exceptions;
 mod fdt;
 mod gpt;
 mod heap;
 mod helpers;
 mod hvc;
 mod instance;
 mod memory;
 mod mmu;
 mod rand;
 mod virtio;

 use alloc::boxed::Box;

 use crate::dice::PartialInputs;
 use crate::entry::RebootReason;
 use crate::fdt::modify_for_next_stage;
 use crate::helpers::flush;
 use crate::helpers::GUEST_PAGE_SIZE;
 use crate::instance::get_or_generate_instance_salt;
 use crate::memory::MemoryTracker;
 use crate::virtio::pci;
 use diced_open_dice::bcc_handover_main_flow;
 use diced_open_dice::bcc_handover_parse;
 use diced_open_dice::DiceArtifacts;
 use fdtpci::{PciError, PciInfo};
 use libfdt::Fdt;
 use log::{debug, error, info, trace};
 use pvmfw_avb::verify_payload;
 use pvmfw_avb::DebugLevel;
 use pvmfw_embedded_key::PUBLIC_KEY;

 const NEXT_BCC_SIZE: usize = GUEST_PAGE_SIZE;

 fn main(
     fdt: &mut Fdt,
     signed_kernel: &[u8],
     ramdisk: Option<&[u8]>,
     current_bcc_handover: &[u8],
     debug_policy: Option<&mut [u8]>,
     memory: &mut MemoryTracker,
 ) -> Result<(), RebootReason> {
     info!("pVM firmware");
     debug!("FDT: {:?}", fdt.as_ptr());
     debug!("Signed kernel: {:?} ({:#x} bytes)", signed_kernel.as_ptr(), signed_kernel.len());
     debug!("AVB public key: addr={:?}, size={:#x} ({1})", PUBLIC_KEY.as_ptr(), PUBLIC_KEY.len());
     if let Some(rd) = ramdisk {
         debug!("Ramdisk: {:?} ({:#x} bytes)", rd.as_ptr(), rd.len());
     } else {
         debug!("Ramdisk: None");
     }
     let bcc_handover = bcc_handover_parse(current_bcc_handover).map_err(|e| {
         error!("Invalid BCC Handover: {e:?}");
         RebootReason::InvalidBcc
     })?;
     trace!("BCC: {bcc_handover:x?}");

     // Set up PCI bus for VirtIO devices.
     let pci_info = PciInfo::from_fdt(fdt).map_err(handle_pci_error)?;
     debug!("PCI: {:#x?}", pci_info);
     let mut pci_root = pci::initialise(pci_info, memory)?;

     let verified_boot_data = verify_payload(signed_kernel, ramdisk, PUBLIC_KEY).map_err(|e| {
         error!("Failed to verify the payload: {e}");
         RebootReason::PayloadVerificationError
     })?;

     let next_bcc = heap::aligned_boxed_slice(NEXT_BCC_SIZE, GUEST_PAGE_SIZE).ok_or_else(|| {
         error!("Failed to allocate the next-stage BCC");
         RebootReason::InternalError
     })?;
     // By leaking the slice, its content will be left behind for the next stage.
     let next_bcc = Box::leak(next_bcc);

     let dice_inputs = PartialInputs::new(&verified_boot_data).map_err(|e| {
         error!("Failed to compute partial DICE inputs: {e:?}");
         RebootReason::InternalError
     })?;
     let cdi_seal = DiceArtifacts::cdi_seal(&bcc_handover);
     let (new_instance, salt) = get_or_generate_instance_salt(&mut pci_root, &dice_inputs, cdi_seal)
         .map_err(|e| {
             error!("Failed to get instance.img salt: {e}");
             RebootReason::InternalError
         })?;
     trace!("Got salt from instance.img: {salt:x?}");

     let dice_inputs = dice_inputs.into_input_values(&salt).map_err(|e| {
         error!("Failed to generate DICE inputs: {e:?}");
         RebootReason::InternalError
     })?;
     let _ = bcc_handover_main_flow(current_bcc_handover, &dice_inputs, next_bcc).map_err(|e| {
         error!("Failed to derive next-stage DICE secrets: {e:?}");
         RebootReason::SecretDerivationError
     })?;
     flush(next_bcc);

     let strict_boot = true;
     let debuggable = verified_boot_data.debug_level != DebugLevel::None;
     modify_for_next_stage(fdt, next_bcc, new_instance, strict_boot, debug_policy, debuggable)
         .map_err(|e| {
             error!("Failed to configure device tree: {e}");
             RebootReason::InternalError
         })?;

     info!("Starting payload...");
     Ok(())
 }

 /// Logs the given PCI error and returns the appropriate `RebootReason`.
 fn handle_pci_error(e: PciError) -> RebootReason {
     error!("{}", e);
     match e {
         PciError::FdtErrorPci(_)
         | PciError::FdtNoPci
         | PciError::FdtErrorReg(_)
         | PciError::FdtMissingReg
         | PciError::FdtRegEmpty
         | PciError::FdtRegMissingSize
         | PciError::CamWrongSize(_)
         | PciError::FdtErrorRanges(_)
         | PciError::FdtMissingRanges
         | PciError::RangeAddressMismatch { .. }
         | PciError::NoSuitableRange => RebootReason::InvalidFdt,
     }
 }
	// Copyright 2022, The Android Open Source Project
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	//! pVM firmware.

	#![no_main]
	#![no_std]

	extern crate alloc;

	mod bootargs;
	mod config;
	mod crypto;
	mod dice;
	mod entry;
	mod exceptions;
	mod fdt;
	mod gpt;
	mod heap;
	mod helpers;
	mod hvc;
	mod instance;
	mod memory;
	mod mmu;
	mod rand;
	mod virtio;

	use alloc::boxed::Box;

	use crate::dice::PartialInputs;
	use crate::entry::RebootReason;
	use crate::fdt::modify_for_next_stage;
	use crate::helpers::flush;
	use crate::helpers::GUEST_PAGE_SIZE;
	use crate::instance::get_or_generate_instance_salt;
	use crate::memory::MemoryTracker;
	use crate::virtio::pci;
	use diced_open_dice::bcc_handover_main_flow;
	use diced_open_dice::bcc_handover_parse;
	use diced_open_dice::DiceArtifacts;
	use fdtpci::{PciError, PciInfo};
	use libfdt::Fdt;
	use log::{debug, error, info, trace};
	use pvmfw_avb::verify_payload;
	use pvmfw_avb::DebugLevel;
	use pvmfw_embedded_key::PUBLIC_KEY;

	const NEXT_BCC_SIZE: usize = GUEST_PAGE_SIZE;

	fn main(
	fdt: &mut Fdt,
	signed_kernel: &[u8],
	ramdisk: Option<&[u8]>,
	current_bcc_handover: &[u8],
	debug_policy: Option<&mut [u8]>,
	memory: &mut MemoryTracker,
	) -> Result<(), RebootReason> {
	info!("pVM firmware");
	debug!("FDT: {:?}", fdt.as_ptr());
	debug!("Signed kernel: {:?} ({:#x} bytes)", signed_kernel.as_ptr(), signed_kernel.len());
	debug!("AVB public key: addr={:?}, size={:#x} ({1})", PUBLIC_KEY.as_ptr(), PUBLIC_KEY.len());
	if let Some(rd) = ramdisk {
	debug!("Ramdisk: {:?} ({:#x} bytes)", rd.as_ptr(), rd.len());
	} else {
	debug!("Ramdisk: None");
	}
	let bcc_handover = bcc_handover_parse(current_bcc_handover).map_err(\|e\| {
	error!("Invalid BCC Handover: {e:?}");
	RebootReason::InvalidBcc
	})?;
	trace!("BCC: {bcc_handover:x?}");

	// Set up PCI bus for VirtIO devices.
	let pci_info = PciInfo::from_fdt(fdt).map_err(handle_pci_error)?;
	debug!("PCI: {:#x?}", pci_info);
	let mut pci_root = pci::initialise(pci_info, memory)?;

	let verified_boot_data = verify_payload(signed_kernel, ramdisk, PUBLIC_KEY).map_err(\|e\| {
	error!("Failed to verify the payload: {e}");
	RebootReason::PayloadVerificationError
	})?;

	let next_bcc = heap::aligned_boxed_slice(NEXT_BCC_SIZE, GUEST_PAGE_SIZE).ok_or_else(\|\| {
	error!("Failed to allocate the next-stage BCC");
	RebootReason::InternalError
	})?;
	// By leaking the slice, its content will be left behind for the next stage.
	let next_bcc = Box::leak(next_bcc);

	let dice_inputs = PartialInputs::new(&verified_boot_data).map_err(\|e\| {
	error!("Failed to compute partial DICE inputs: {e:?}");
	RebootReason::InternalError
	})?;
	let cdi_seal = DiceArtifacts::cdi_seal(&bcc_handover);
	let (new_instance, salt) = get_or_generate_instance_salt(&mut pci_root, &dice_inputs, cdi_seal)
	.map_err(\|e\| {
	error!("Failed to get instance.img salt: {e}");
	RebootReason::InternalError
	})?;
	trace!("Got salt from instance.img: {salt:x?}");

	let dice_inputs = dice_inputs.into_input_values(&salt).map_err(\|e\| {
	error!("Failed to generate DICE inputs: {e:?}");
	RebootReason::InternalError
	})?;
	let _ = bcc_handover_main_flow(current_bcc_handover, &dice_inputs, next_bcc).map_err(\|e\| {
	error!("Failed to derive next-stage DICE secrets: {e:?}");
	RebootReason::SecretDerivationError
	})?;
	flush(next_bcc);

	let strict_boot = true;
	let debuggable = verified_boot_data.debug_level != DebugLevel::None;
	modify_for_next_stage(fdt, next_bcc, new_instance, strict_boot, debug_policy, debuggable)
	.map_err(\|e\| {
	error!("Failed to configure device tree: {e}");
	RebootReason::InternalError
	})?;

	info!("Starting payload...");
	Ok(())
	}

	/// Logs the given PCI error and returns the appropriate `RebootReason`.
	fn handle_pci_error(e: PciError) -> RebootReason {
	error!("{}", e);
	match e {
	PciError::FdtErrorPci(_)
	\| PciError::FdtNoPci
	\| PciError::FdtErrorReg(_)
	\| PciError::FdtMissingReg
	\| PciError::FdtRegEmpty
	\| PciError::FdtRegMissingSize
	\| PciError::CamWrongSize(_)
	\| PciError::FdtErrorRanges(_)
	\| PciError::FdtMissingRanges
	\| PciError::RangeAddressMismatch { .. }
	\| PciError::NoSuitableRange => RebootReason::InvalidFdt,
	}
	}