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|
//! UEFI Reference Specification Protocol Constants and Definitions
//!
//! This project provides protocol constants and definitions as defined in the UEFI Reference
//! Specification. The aim is to provide all these constants as C-ABI compatible imports to rust.
//! Safe rust abstractions over the UEFI API are out of scope of this project. That is, the
//! purpose is really just to extract all the bits and pieces from the specification and provide
//! them as rust types and constants.
//!
//! While we strongly recommend using safe abstractions to interact with UEFI systems, this
//! project serves both as base to write those abstractions, but also as last resort if you have
//! to deal with quirks and peculiarities of UEFI systems directly. Therefore, several examples
//! are included, which show how to interact with UEFI systems from rust. These serve both as
//! documentation for anyone interested in how the system works, but also as base for anyone
//! implementing safe abstractions on top.
//!
//! # Target Configuration
//!
//! Rust code can be compiled natively for UEFI systems. However, you are quite unlikely to have a
//! rust compiler running in an UEFI environment. Therefore, you will most likely want to cross
//! compile your rust code for UEFI systems. To do this, you need a target-configuration for UEFI
//! systems. As of rust-1.61, upstream rust includes the following UEFI targets:
//!
//! * `aarch64-unknown-uefi`: A native UEFI target for aarch64 systems (64bit ARM).
//! * `i686-unknown-uefi`: A native UEFI target for i686 systems (32bit Intel x86).
//! * `x86_64-unknown-uefi`: A native UEFI target for x86-64 systems (64bit Intel x86).
//!
//! If none of these targets match your architecture, you have to create the target specification
//! yourself. Feel free to contact the `r-efi` project for help.
//!
//! # Transpose Guidelines
//!
//! The UEFI specification provides C language symbols and definitions of all
//! its protocols and features. Those are integral parts of the specification
//! and UEFI programming is often tightly coupled with the C language. For
//! better compatibility to existing UEFI documentation, all the rust symbols
//! are transposed from C following strict rules, aiming for close similarity
//! to specification. This section gives a rationale on some of the less
//! obvious choices and tries to describe as many of those rules as possible.
//!
//! * `no enums`: Rust enums do not allow random discriminant values. However,
//! many UEFI enumerations use reserved ranges for vendor defined values.
//! These cannot be represented with rust enums in an efficient manner.
//! Hence, any enumerations are turned into rust constants with an
//! accompanying type alias.
//!
//! A detailed discussion can be found in:
//!
//! ```gitlog
//! commit 401a91901e860a5c0cd0f92b75dda0a72cf65322
//! Author: David Rheinsberg <david.rheinsberg@gmail.com>
//! Date: Wed Apr 21 12:07:07 2021 +0200
//!
//! r-efi: convert enums to constants
//! ```
//!
//! * `no incomplete types`: Several structures use incomplete structure types
//! by using an unbound array as last member. While rust can easily
//! represent those within its type-system, such structures become DSTs,
//! hence even raw pointers to them become fat-pointers, and would thus
//! violate the UEFI ABI.
//!
//! Instead, we use const-generics to allow compile-time adjustment of the
//! variable-sized structures, with a default value of 0. This allows
//! computing different sizes of the structures without any runtime overhead.
//!
//! * `nullable callbacks as Option`: Rust has no raw function pointers, but
//! just normal Rust function pointers. Those, however, have no valid null
//! value. The Rust ABI guarantees that `Option<fn ...>` is an C-ABI
//! compatible replacement for nullable function pointers, with `None` being
//! mapped to `NULL`. Hence, whenever UEFI APIs require nullable function
//! pointers, we use `Option<fn ...>`.
//!
//! * `prefer *mut over *const`: Whenever we transpose pointers from the
//! specification into Rust, we prefer `*mut` in almost all cases. `*const`
//! should only be used if the underlying value is known not to be accessible
//! via any other mutable pointer type. Since this is rarely the case in
//! UEFI, we avoid it.
//!
//! The reasoning is that Rust allows coercing immutable types into `*const`
//! pointers, without any explicit casting required. However, immutable Rust
//! references require that no other mutable reference exists simultaneously.
//! This is not a guarantee of `const`-pointers in C / UEFI, hence this
//! coercion is usually ill-advised or even wrong.
//!
//! Lastly, note that `*mut` and `*const` and be `as`-casted in both
//! directions without violating any Rust guarantees. Any UB concerns always
//! stem from the safety guarantees of the surrounding code, not of the
//! raw-pointer handling.
//!
//! # Examples
//!
//! To write free-standing UEFI applications, you need to disable the entry-point provided by rust
//! and instead provide your own. Most target-configurations look for a function called `efi_main`
//! during linking and set it as entry point. If you use the target-configurations provided with
//! upstream rust, they will pick the function called `efi_main` as entry-point.
//!
//! The following example shows a minimal UEFI application, which simply returns success upon
//! invocation. Note that you must provide your own panic-handler when running without `libstd`.
//! In our case, we use a trivial implementation that simply loops forever.
//!
//! ```ignore
//! #![no_main]
//! #![no_std]
//!
//! use r_efi::efi;
//!
//! #[panic_handler]
//! fn panic_handler(_info: &core::panic::PanicInfo) -> ! {
//! loop {}
//! }
//!
//! #[export_name = "efi_main"]
//! pub extern fn main(_h: efi::Handle, _st: *mut efi::SystemTable) -> efi::Status {
//! efi::Status::SUCCESS
//! }
//! ```
// Mark this crate as `no_std`. We have no std::* dependencies (and we better don't have them),
// so no reason to require it. This does not mean that you cannot use std::* with UEFI. You have
// to port it to UEFI first, though.
//
// In case of unit-test compilation, we pull in `std` and drop the `no_std` marker. This allows
// basic unit-tests on the compilation host. For integration tests, we have separate compilation
// units, so they will be unaffected by this.
#![cfg_attr(not(test), no_std)]
// Import the different core modules. We separate them into different modules to make it easier to
// work on them and describe what each part implements. This is different to the reference
// implementation, which uses a flat namespace due to its origins in the C language. For
// compatibility, we provide this flat namespace as well. See the `efi` submodule.
#[macro_use]
pub mod base;
#[macro_use]
pub mod hii;
#[macro_use]
pub mod system;
// Import the protocols. Each protocol is separated into its own module, readily imported by the
// meta `protocols` module. Note that this puts all symbols into their respective protocol
// namespace, thus clearly separating them (unlike the UEFI Specification, which more often than
// not violates its own namespacing).
pub mod protocols;
// Import vendor protocols. They are just like protocols in `protocols`, but
// separated for better namespacing.
pub mod vendor;
/// Flat EFI Namespace
///
/// The EFI namespace re-exports all symbols in a single, flat namespace. This allows mirroring
/// the entire EFI namespace as given in the specification and makes it easier to refer to them
/// with the same names as the reference C implementation.
///
/// Note that the individual protocols are put into submodules. The specification does this in
/// most parts as well (by prefixing all symbols). This is not true in all cases, as the
/// specification suffers from lack of namespaces in the reference C language. However, we decided
/// to namespace the remaining bits as well, for better consistency throughout the API. This
/// should be self-explanatory in nearly all cases.
pub mod efi {
//
// Re-export base
//
pub use crate::base::Boolean;
pub use crate::base::Char16;
pub use crate::base::Char8;
pub use crate::base::Event;
pub use crate::base::Guid;
pub use crate::base::Handle;
pub use crate::base::ImageEntryPoint;
pub use crate::base::IpAddress;
pub use crate::base::Ipv4Address;
pub use crate::base::Ipv6Address;
pub use crate::base::Lba;
pub use crate::base::MacAddress;
pub use crate::base::PhysicalAddress;
pub use crate::base::Status;
pub use crate::base::Tpl;
pub use crate::base::VirtualAddress;
//
// Re-export system
//
pub use crate::system::Time;
pub use crate::system::TimeCapabilities;
pub use crate::system::TIME_ADJUST_DAYLIGHT;
pub use crate::system::TIME_IN_DAYLIGHT;
pub use crate::system::UNSPECIFIED_TIMEZONE;
pub use crate::system::VariableAuthentication;
pub use crate::system::VariableAuthentication2;
pub use crate::system::VariableAuthentication3;
pub use crate::system::VariableAuthentication3CertId;
pub use crate::system::VariableAuthentication3Nonce;
pub use crate::system::HARDWARE_ERROR_VARIABLE_GUID;
pub use crate::system::VARIABLE_APPEND_WRITE;
pub use crate::system::VARIABLE_AUTHENTICATED_WRITE_ACCESS;
pub use crate::system::VARIABLE_AUTHENTICATION_3_CERT_ID_SHA256;
pub use crate::system::VARIABLE_AUTHENTICATION_3_NONCE_TYPE;
pub use crate::system::VARIABLE_AUTHENTICATION_3_TIMESTAMP_TYPE;
pub use crate::system::VARIABLE_BOOTSERVICE_ACCESS;
pub use crate::system::VARIABLE_ENHANCED_AUTHENTICATED_ACCESS;
pub use crate::system::VARIABLE_HARDWARE_ERROR_RECORD;
pub use crate::system::VARIABLE_NON_VOLATILE;
pub use crate::system::VARIABLE_RUNTIME_ACCESS;
pub use crate::system::VARIABLE_TIME_BASED_AUTHENTICATED_WRITE_ACCESS;
pub use crate::system::OPTIONAL_POINTER;
pub use crate::system::ResetType;
pub use crate::system::RESET_COLD;
pub use crate::system::RESET_PLATFORM_SPECIFIC;
pub use crate::system::RESET_SHUTDOWN;
pub use crate::system::RESET_WARM;
pub use crate::system::CapsuleBlockDescriptor;
pub use crate::system::CapsuleBlockDescriptorUnion;
pub use crate::system::CapsuleHeader;
pub use crate::system::CapsuleResultVariableFMP;
pub use crate::system::CapsuleResultVariableHeader;
pub use crate::system::CAPSULE_FLAGS_INITIATE_RESET;
pub use crate::system::CAPSULE_FLAGS_PERSIST_ACROSS_RESET;
pub use crate::system::CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE;
pub use crate::system::CAPSULE_REPORT_GUID;
pub use crate::system::OS_INDICATIONS_BOOT_TO_FW_UI;
pub use crate::system::OS_INDICATIONS_CAPSULE_RESULT_VAR_SUPPORTED;
pub use crate::system::OS_INDICATIONS_FILE_CAPSULE_DELIVERY_SUPPORTED;
pub use crate::system::OS_INDICATIONS_FMP_CAPSULE_SUPPORTED;
pub use crate::system::OS_INDICATIONS_START_OS_RECOVERY;
pub use crate::system::OS_INDICATIONS_START_PLATFORM_RECOVERY;
pub use crate::system::OS_INDICATIONS_TIMESTAMP_REVOCATION;
pub use crate::system::EventNotify;
pub use crate::system::TimerDelay;
pub use crate::system::EVENT_GROUP_EXIT_BOOT_SERVICES;
pub use crate::system::EVENT_GROUP_MEMORY_MAP_CHANGE;
pub use crate::system::EVENT_GROUP_READY_TO_BOOT;
pub use crate::system::EVENT_GROUP_RESET_SYSTEM;
pub use crate::system::EVENT_GROUP_VIRTUAL_ADDRESS_CHANGE;
pub use crate::system::EVT_NOTIFY_SIGNAL;
pub use crate::system::EVT_NOTIFY_WAIT;
pub use crate::system::EVT_RUNTIME;
pub use crate::system::EVT_SIGNAL_EXIT_BOOT_SERVICES;
pub use crate::system::EVT_SIGNAL_VIRTUAL_ADDRESS_CHANGE;
pub use crate::system::EVT_TIMER;
pub use crate::system::TIMER_CANCEL;
pub use crate::system::TIMER_PERIODIC;
pub use crate::system::TIMER_RELATIVE;
pub use crate::system::TPL_APPLICATION;
pub use crate::system::TPL_CALLBACK;
pub use crate::system::TPL_HIGH_LEVEL;
pub use crate::system::TPL_NOTIFY;
pub use crate::system::AllocateType;
pub use crate::system::MemoryDescriptor;
pub use crate::system::MemoryType;
pub use crate::system::ACPI_MEMORY_NVS;
pub use crate::system::ACPI_RECLAIM_MEMORY;
pub use crate::system::ALLOCATE_ADDRESS;
pub use crate::system::ALLOCATE_ANY_PAGES;
pub use crate::system::ALLOCATE_MAX_ADDRESS;
pub use crate::system::BOOT_SERVICES_CODE;
pub use crate::system::BOOT_SERVICES_DATA;
pub use crate::system::CONVENTIONAL_MEMORY;
pub use crate::system::LOADER_CODE;
pub use crate::system::LOADER_DATA;
pub use crate::system::MEMORY_DESCRIPTOR_VERSION;
pub use crate::system::MEMORY_MAPPED_IO;
pub use crate::system::MEMORY_MAPPED_IO_PORT_SPACE;
pub use crate::system::MEMORY_MORE_RELIABLE;
pub use crate::system::MEMORY_NV;
pub use crate::system::MEMORY_RO;
pub use crate::system::MEMORY_RP;
pub use crate::system::MEMORY_RUNTIME;
pub use crate::system::MEMORY_UC;
pub use crate::system::MEMORY_UCE;
pub use crate::system::MEMORY_WB;
pub use crate::system::MEMORY_WC;
pub use crate::system::MEMORY_WP;
pub use crate::system::MEMORY_WT;
pub use crate::system::MEMORY_XP;
pub use crate::system::PAL_CODE;
pub use crate::system::PERSISTENT_MEMORY;
pub use crate::system::RESERVED_MEMORY_TYPE;
pub use crate::system::RUNTIME_SERVICES_CODE;
pub use crate::system::RUNTIME_SERVICES_DATA;
pub use crate::system::UNUSABLE_MEMORY;
pub use crate::system::InterfaceType;
pub use crate::system::LocateSearchType;
pub use crate::system::OpenProtocolInformationEntry;
pub use crate::system::ALL_HANDLES;
pub use crate::system::BY_PROTOCOL;
pub use crate::system::BY_REGISTER_NOTIFY;
pub use crate::system::NATIVE_INTERFACE;
pub use crate::system::OPEN_PROTOCOL_BY_CHILD_CONTROLLER;
pub use crate::system::OPEN_PROTOCOL_BY_DRIVER;
pub use crate::system::OPEN_PROTOCOL_BY_HANDLE_PROTOCOL;
pub use crate::system::OPEN_PROTOCOL_EXCLUSIVE;
pub use crate::system::OPEN_PROTOCOL_GET_PROTOCOL;
pub use crate::system::OPEN_PROTOCOL_TEST_PROTOCOL;
pub use crate::system::ConfigurationTable;
pub use crate::system::MemoryAttributesTable;
pub use crate::system::PropertiesTable;
pub use crate::system::MEMORY_ATTRIBUTES_TABLE_GUID;
pub use crate::system::MEMORY_ATTRIBUTES_TABLE_VERSION;
pub use crate::system::PROPERTIES_RUNTIME_MEMORY_PROTECTION_NON_EXECUTABLE_PE_DATA;
pub use crate::system::PROPERTIES_TABLE_GUID;
pub use crate::system::PROPERTIES_TABLE_VERSION;
pub use crate::system::BootServices;
pub use crate::system::RuntimeServices;
pub use crate::system::SystemTable;
pub use crate::system::TableHeader;
pub use crate::system::BOOT_SERVICES_REVISION;
pub use crate::system::BOOT_SERVICES_SIGNATURE;
pub use crate::system::RUNTIME_SERVICES_REVISION;
pub use crate::system::RUNTIME_SERVICES_SIGNATURE;
pub use crate::system::SPECIFICATION_REVISION;
pub use crate::system::SYSTEM_TABLE_REVISION_1_02;
pub use crate::system::SYSTEM_TABLE_REVISION_1_10;
pub use crate::system::SYSTEM_TABLE_REVISION_2_00;
pub use crate::system::SYSTEM_TABLE_REVISION_2_10;
pub use crate::system::SYSTEM_TABLE_REVISION_2_20;
pub use crate::system::SYSTEM_TABLE_REVISION_2_30;
pub use crate::system::SYSTEM_TABLE_REVISION_2_31;
pub use crate::system::SYSTEM_TABLE_REVISION_2_40;
pub use crate::system::SYSTEM_TABLE_REVISION_2_50;
pub use crate::system::SYSTEM_TABLE_REVISION_2_60;
pub use crate::system::SYSTEM_TABLE_REVISION_2_70;
pub use crate::system::SYSTEM_TABLE_SIGNATURE;
//
// Re-export HII
//
pub use crate::hii;
//
// Re-export protocols
//
pub use crate::protocols;
//
// Re-export vendor.
//
pub use crate::vendor;
}
|