guest/pvmfw/src/entry.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.

 //! Low-level entry and exit points of pvmfw.

 use crate::arch::payload::jump_to_payload;
 use crate::config;
 use crate::memory::MemorySlices;
 use core::slice;
 use log::error;
 use log::warn;
 use log::LevelFilter;
 use vmbase::{
     configure_heap, console_writeln, limit_stack_size, main,
     memory::{
         map_image_footer, unshare_all_memory, unshare_all_mmio_except_uart, unshare_uart,
         MemoryTrackerError, SIZE_128KB, SIZE_4KB,
     },
     power::reboot,
 };
 use zeroize::Zeroize;

 #[derive(Debug, Clone)]
 pub enum RebootReason {
     /// A malformed BCC was received.
     InvalidBcc,
     /// An invalid configuration was appended to pvmfw.
     InvalidConfig,
     /// An unexpected internal error happened.
     InternalError,
     /// The provided FDT was invalid.
     InvalidFdt,
     /// The provided payload was invalid.
     InvalidPayload,
     /// The provided ramdisk was invalid.
     InvalidRamdisk,
     /// Failed to verify the payload.
     PayloadVerificationError,
     /// DICE layering process failed.
     SecretDerivationError,
 }

 impl RebootReason {
     pub fn as_avf_reboot_string(&self) -> &'static str {
         match self {
             Self::InvalidBcc => "PVM_FIRMWARE_INVALID_BCC",
             Self::InvalidConfig => "PVM_FIRMWARE_INVALID_CONFIG_DATA",
             Self::InternalError => "PVM_FIRMWARE_INTERNAL_ERROR",
             Self::InvalidFdt => "PVM_FIRMWARE_INVALID_FDT",
             Self::InvalidPayload => "PVM_FIRMWARE_INVALID_PAYLOAD",
             Self::InvalidRamdisk => "PVM_FIRMWARE_INVALID_RAMDISK",
             Self::PayloadVerificationError => "PVM_FIRMWARE_PAYLOAD_VERIFICATION_FAILED",
             Self::SecretDerivationError => "PVM_FIRMWARE_SECRET_DERIVATION_FAILED",
         }
     }
 }

 main!(start);
 configure_heap!(SIZE_128KB);
 limit_stack_size!(SIZE_4KB * 12);

 #[derive(Debug)]
 enum NextStage {
     LinuxBoot(usize),
     LinuxBootWithUart(usize),
 }

 /// Entry point for pVM firmware.
 pub fn start(fdt_address: u64, payload_start: u64, payload_size: u64, _arg3: u64) {
     let fdt_address = fdt_address.try_into().unwrap();
     let payload_start = payload_start.try_into().unwrap();
     let payload_size = payload_size.try_into().unwrap();

     let reboot_reason = match main_wrapper(fdt_address, payload_start, payload_size) {
         Err(r) => r,
         Ok((next_stage, slices)) => match next_stage {
             NextStage::LinuxBootWithUart(ep) => jump_to_payload(ep, &slices),
             NextStage::LinuxBoot(ep) => {
                 if let Err(e) = unshare_uart() {
                     error!("Failed to unmap UART: {e}");
                     RebootReason::InternalError
                 } else {
                     jump_to_payload(ep, &slices)
                 }
             }
         },
     };

     const REBOOT_REASON_CONSOLE: usize = 1;
     console_writeln!(REBOOT_REASON_CONSOLE, "{}", reboot_reason.as_avf_reboot_string());
     reboot()

     // if we reach this point and return, vmbase::entry::rust_entry() will call power::shutdown().
 }

 /// Sets up the environment for main() and wraps its result for start().
 ///
 /// Provide the abstractions necessary for start() to abort the pVM boot and for main() to run with
 /// the assumption that its environment has been properly configured.
 fn main_wrapper<'a>(
     fdt: usize,
     payload: usize,
     payload_size: usize,
 ) -> Result<(NextStage, MemorySlices<'a>), RebootReason> {
     // Limitations in this function:
     // - only access MMIO once (and while) it has been mapped and configured
     // - only perform logging once the logger has been initialized
     // - only access non-pvmfw memory once (and while) it has been mapped

     log::set_max_level(LevelFilter::Info);

     let appended_data = get_appended_data_slice().map_err(|e| {
         error!("Failed to map the appended data: {e}");
         RebootReason::InternalError
     })?;

     let appended = AppendedPayload::new(appended_data).ok_or_else(|| {
         error!("No valid configuration found");
         RebootReason::InvalidConfig
     })?;

     let config_entries = appended.get_entries();

     let mut slices = MemorySlices::new(fdt, payload, payload_size)?;

     // This wrapper allows main() to be blissfully ignorant of platform details.
     let (next_bcc, debuggable_payload) = crate::main(
         slices.fdt,
         slices.kernel,
         slices.ramdisk,
         config_entries.bcc,
         config_entries.debug_policy,
         config_entries.vm_dtbo,
         config_entries.vm_ref_dt,
     )?;
     slices.add_dice_chain(next_bcc);
     // Keep UART MMIO_GUARD-ed for debuggable payloads, to enable earlycon.
     let keep_uart = cfg!(debuggable_vms_improvements) && debuggable_payload;

     // Writable-dirty regions will be flushed when MemoryTracker is dropped.
     config_entries.bcc.zeroize();

     unshare_all_mmio_except_uart().map_err(|e| {
         error!("Failed to unshare MMIO ranges: {e}");
         RebootReason::InternalError
     })?;
     unshare_all_memory();

     let next_stage = select_next_stage(slices.kernel, keep_uart);

     Ok((next_stage, slices))
 }

 fn select_next_stage(kernel: &[u8], keep_uart: bool) -> NextStage {
     if keep_uart {
         NextStage::LinuxBootWithUart(kernel.as_ptr() as _)
     } else {
         NextStage::LinuxBoot(kernel.as_ptr() as _)
     }
 }

 fn get_appended_data_slice() -> Result<&'static mut [u8], MemoryTrackerError> {
     let range = map_image_footer()?;
     // SAFETY: This region was just mapped for the first time (as map_image_footer() didn't fail)
     // and the linker script prevents it from overlapping with other objects.
     Ok(unsafe { slice::from_raw_parts_mut(range.start as *mut u8, range.len()) })
 }

 enum AppendedPayload<'a> {
     /// Configuration data.
     Config(config::Config<'a>),
     /// Deprecated raw BCC, as used in Android T.
     LegacyBcc(&'a mut [u8]),
 }

 impl<'a> AppendedPayload<'a> {
     fn new(data: &'a mut [u8]) -> Option<Self> {
         // The borrow checker gets confused about the ownership of data (see inline comments) so we
         // intentionally obfuscate it using a raw pointer; see a similar issue (still not addressed
         // in v1.77) in https://users.rust-lang.org/t/78467.
         let data_ptr = data as *mut [u8];

         // Config::new() borrows data as mutable ...
         match config::Config::new(data) {
             // ... so this branch has a mutable reference to data, from the Ok(Config<'a>). But ...
             Ok(valid) => Some(Self::Config(valid)),
             // ... if Config::new(data).is_err(), the Err holds no ref to data. However ...
             Err(config::Error::InvalidMagic) if cfg!(feature = "legacy") => {
                 // ... the borrow checker still complains about a second mutable ref without this.
                 // SAFETY: Pointer to a valid mut (not accessed elsewhere), 'a lifetime re-used.
                 let data: &'a mut _ = unsafe { &mut *data_ptr };

                 const BCC_SIZE: usize = SIZE_4KB;
                 warn!("Assuming the appended data at {:?} to be a raw BCC", data.as_ptr());
                 Some(Self::LegacyBcc(&mut data[..BCC_SIZE]))
             }
             Err(e) => {
                 error!("Invalid configuration data at {data_ptr:?}: {e}");
                 None
             }
         }
     }

     fn get_entries(self) -> config::Entries<'a> {
         match self {
             Self::Config(cfg) => cfg.get_entries(),
             Self::LegacyBcc(bcc) => config::Entries { bcc, ..Default::default() },
         }
     }
 }
	// 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.

	//! Low-level entry and exit points of pvmfw.

	use crate::arch::payload::jump_to_payload;
	use crate::config;
	use crate::memory::MemorySlices;
	use core::slice;
	use log::error;
	use log::warn;
	use log::LevelFilter;
	use vmbase::{
	configure_heap, console_writeln, limit_stack_size, main,
	memory::{
	map_image_footer, unshare_all_memory, unshare_all_mmio_except_uart, unshare_uart,
	MemoryTrackerError, SIZE_128KB, SIZE_4KB,
	},
	power::reboot,
	};
	use zeroize::Zeroize;

	#[derive(Debug, Clone)]
	pub enum RebootReason {
	/// A malformed BCC was received.
	InvalidBcc,
	/// An invalid configuration was appended to pvmfw.
	InvalidConfig,
	/// An unexpected internal error happened.
	InternalError,
	/// The provided FDT was invalid.
	InvalidFdt,
	/// The provided payload was invalid.
	InvalidPayload,
	/// The provided ramdisk was invalid.
	InvalidRamdisk,
	/// Failed to verify the payload.
	PayloadVerificationError,
	/// DICE layering process failed.
	SecretDerivationError,
	}

	impl RebootReason {
	pub fn as_avf_reboot_string(&self) -> &'static str {
	match self {
	Self::InvalidBcc => "PVM_FIRMWARE_INVALID_BCC",
	Self::InvalidConfig => "PVM_FIRMWARE_INVALID_CONFIG_DATA",
	Self::InternalError => "PVM_FIRMWARE_INTERNAL_ERROR",
	Self::InvalidFdt => "PVM_FIRMWARE_INVALID_FDT",
	Self::InvalidPayload => "PVM_FIRMWARE_INVALID_PAYLOAD",
	Self::InvalidRamdisk => "PVM_FIRMWARE_INVALID_RAMDISK",
	Self::PayloadVerificationError => "PVM_FIRMWARE_PAYLOAD_VERIFICATION_FAILED",
	Self::SecretDerivationError => "PVM_FIRMWARE_SECRET_DERIVATION_FAILED",
	}
	}
	}

	main!(start);
	configure_heap!(SIZE_128KB);
	limit_stack_size!(SIZE_4KB * 12);

	#[derive(Debug)]
	enum NextStage {
	LinuxBoot(usize),
	LinuxBootWithUart(usize),
	}

	/// Entry point for pVM firmware.
	pub fn start(fdt_address: u64, payload_start: u64, payload_size: u64, _arg3: u64) {
	let fdt_address = fdt_address.try_into().unwrap();
	let payload_start = payload_start.try_into().unwrap();
	let payload_size = payload_size.try_into().unwrap();

	let reboot_reason = match main_wrapper(fdt_address, payload_start, payload_size) {
	Err(r) => r,
	Ok((next_stage, slices)) => match next_stage {
	NextStage::LinuxBootWithUart(ep) => jump_to_payload(ep, &slices),
	NextStage::LinuxBoot(ep) => {
	if let Err(e) = unshare_uart() {
	error!("Failed to unmap UART: {e}");
	RebootReason::InternalError
	} else {
	jump_to_payload(ep, &slices)
	}
	}
	},
	};

	const REBOOT_REASON_CONSOLE: usize = 1;
	console_writeln!(REBOOT_REASON_CONSOLE, "{}", reboot_reason.as_avf_reboot_string());
	reboot()

	// if we reach this point and return, vmbase::entry::rust_entry() will call power::shutdown().
	}

	/// Sets up the environment for main() and wraps its result for start().
	///
	/// Provide the abstractions necessary for start() to abort the pVM boot and for main() to run with
	/// the assumption that its environment has been properly configured.
	fn main_wrapper<'a>(
	fdt: usize,
	payload: usize,
	payload_size: usize,
	) -> Result<(NextStage, MemorySlices<'a>), RebootReason> {
	// Limitations in this function:
	// - only access MMIO once (and while) it has been mapped and configured
	// - only perform logging once the logger has been initialized
	// - only access non-pvmfw memory once (and while) it has been mapped

	log::set_max_level(LevelFilter::Info);

	let appended_data = get_appended_data_slice().map_err(\|e\| {
	error!("Failed to map the appended data: {e}");
	RebootReason::InternalError
	})?;

	let appended = AppendedPayload::new(appended_data).ok_or_else(\|\| {
	error!("No valid configuration found");
	RebootReason::InvalidConfig
	})?;

	let config_entries = appended.get_entries();

	let mut slices = MemorySlices::new(fdt, payload, payload_size)?;

	// This wrapper allows main() to be blissfully ignorant of platform details.
	let (next_bcc, debuggable_payload) = crate::main(
	slices.fdt,
	slices.kernel,
	slices.ramdisk,
	config_entries.bcc,
	config_entries.debug_policy,
	config_entries.vm_dtbo,
	config_entries.vm_ref_dt,
	)?;
	slices.add_dice_chain(next_bcc);
	// Keep UART MMIO_GUARD-ed for debuggable payloads, to enable earlycon.
	let keep_uart = cfg!(debuggable_vms_improvements) && debuggable_payload;

	// Writable-dirty regions will be flushed when MemoryTracker is dropped.
	config_entries.bcc.zeroize();

	unshare_all_mmio_except_uart().map_err(\|e\| {
	error!("Failed to unshare MMIO ranges: {e}");
	RebootReason::InternalError
	})?;
	unshare_all_memory();

	let next_stage = select_next_stage(slices.kernel, keep_uart);

	Ok((next_stage, slices))
	}

	fn select_next_stage(kernel: &[u8], keep_uart: bool) -> NextStage {
	if keep_uart {
	NextStage::LinuxBootWithUart(kernel.as_ptr() as _)
	} else {
	NextStage::LinuxBoot(kernel.as_ptr() as _)
	}
	}

	fn get_appended_data_slice() -> Result<&'static mut [u8], MemoryTrackerError> {
	let range = map_image_footer()?;
	// SAFETY: This region was just mapped for the first time (as map_image_footer() didn't fail)
	// and the linker script prevents it from overlapping with other objects.
	Ok(unsafe { slice::from_raw_parts_mut(range.start as *mut u8, range.len()) })
	}

	enum AppendedPayload<'a> {
	/// Configuration data.
	Config(config::Config<'a>),
	/// Deprecated raw BCC, as used in Android T.
	LegacyBcc(&'a mut [u8]),
	}

	impl<'a> AppendedPayload<'a> {
	fn new(data: &'a mut [u8]) -> Option<Self> {
	// The borrow checker gets confused about the ownership of data (see inline comments) so we
	// intentionally obfuscate it using a raw pointer; see a similar issue (still not addressed
	// in v1.77) in https://users.rust-lang.org/t/78467.
	let data_ptr = data as *mut [u8];

	// Config::new() borrows data as mutable ...
	match config::Config::new(data) {
	// ... so this branch has a mutable reference to data, from the Ok(Config<'a>). But ...
	Ok(valid) => Some(Self::Config(valid)),
	// ... if Config::new(data).is_err(), the Err holds no ref to data. However ...
	Err(config::Error::InvalidMagic) if cfg!(feature = "legacy") => {
	// ... the borrow checker still complains about a second mutable ref without this.
	// SAFETY: Pointer to a valid mut (not accessed elsewhere), 'a lifetime re-used.
	let data: &'a mut _ = unsafe { &mut *data_ptr };

	const BCC_SIZE: usize = SIZE_4KB;
	warn!("Assuming the appended data at {:?} to be a raw BCC", data.as_ptr());
	Some(Self::LegacyBcc(&mut data[..BCC_SIZE]))
	}
	Err(e) => {
	error!("Invalid configuration data at {data_ptr:?}: {e}");
	None
	}
	}
	}

	fn get_entries(self) -> config::Entries<'a> {
	match self {
	Self::Config(cfg) => cfg.get_entries(),
	Self::LegacyBcc(bcc) => config::Entries { bcc, ..Default::default() },
	}
	}
	}