352 lines
10 KiB
Rust
352 lines
10 KiB
Rust
//! Minimal startup / runtime for RISC-V CPU's
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//!
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//! # Minimum Supported Rust Version (MSRV)
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//!
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//! This crate is guaranteed to compile on stable Rust 1.31 and up. It *might*
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//! compile with older versions but that may change in any new patch release.
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//!
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//! # Features
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//!
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//! This crate provides
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//!
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//! - Before main initialization of the `.bss` and `.data` sections.
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//!
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//! - `#[entry]` to declare the entry point of the program
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//! - `#[pre_init]` to run code *before* `static` variables are initialized
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//!
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//! - A linker script that encodes the memory layout of a generic RISC-V
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//! microcontroller. This linker script is missing some information that must
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//! be supplied through a `memory.x` file (see example below). This file
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//! must be supplied using rustflags and listed *before* `link.x`. Arbitrary
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//! filename can be use instead of `memory.x`.
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//!
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//! - A `_sheap` symbol at whose address you can locate a heap.
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//!
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//! ``` text
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//! $ cargo new --bin app && cd $_
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//!
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//! $ # add this crate as a dependency
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//! $ edit Cargo.toml && cat $_
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//! [dependencies]
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//! riscv-rt = "0.6.1"
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//! panic-halt = "0.2.0"
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//!
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//! $ # memory layout of the device
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//! $ edit memory.x && cat $_
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//! MEMORY
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//! {
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//! RAM : ORIGIN = 0x80000000, LENGTH = 16K
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//! FLASH : ORIGIN = 0x20000000, LENGTH = 16M
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//! }
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//!
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//! REGION_ALIAS("REGION_TEXT", FLASH);
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//! REGION_ALIAS("REGION_RODATA", FLASH);
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//! REGION_ALIAS("REGION_DATA", RAM);
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//! REGION_ALIAS("REGION_BSS", RAM);
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//! REGION_ALIAS("REGION_HEAP", RAM);
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//! REGION_ALIAS("REGION_STACK", RAM);
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//!
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//! $ edit src/main.rs && cat $_
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//! ```
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//!
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//! ``` ignore,no_run
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//! #![no_std]
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//! #![no_main]
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//!
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//! extern crate panic_halt;
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//!
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//! use riscv_rt::entry;
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//!
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//! // use `main` as the entry point of this application
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//! // `main` is not allowed to return
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//! #[entry]
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//! fn main() -> ! {
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//! // do something here
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//! loop { }
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//! }
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//! ```
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//!
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//! ``` text
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//! $ mkdir .cargo && edit .cargo/config && cat $_
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//! [target.riscv32imac-unknown-none-elf]
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//! rustflags = [
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//! "-C", "link-arg=-Tmemory.x",
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//! "-C", "link-arg=-Tlink.x",
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//! ]
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//!
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//! [build]
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//! target = "riscv32imac-unknown-none-elf"
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//! $ edit build.rs && cat $_
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//! ```
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//!
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//! ``` ignore,no_run
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//! use std::env;
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//! use std::fs::File;
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//! use std::io::Write;
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//! use std::path::Path;
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//!
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//! /// Put the linker script somewhere the linker can find it.
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//! fn main() {
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//! let out_dir = env::var("OUT_DIR").expect("No out dir");
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//! let dest_path = Path::new(&out_dir);
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//! let mut f = File::create(&dest_path.join("memory.x"))
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//! .expect("Could not create file");
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//!
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//! f.write_all(include_bytes!("memory.x"))
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//! .expect("Could not write file");
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//!
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//! println!("cargo:rustc-link-search={}", dest_path.display());
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//!
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//! println!("cargo:rerun-if-changed=memory.x");
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//! println!("cargo:rerun-if-changed=build.rs");
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//! }
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//! ```
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//!
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//! ``` text
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//! $ cargo build
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//!
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//! $ riscv32-unknown-elf-objdump -Cd $(find target -name app) | head
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//!
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//! Disassembly of section .text:
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//!
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//! 20000000 <_start>:
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//! 20000000: 800011b7 lui gp,0x80001
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//! 20000004: 80018193 addi gp,gp,-2048 # 80000800 <_stack_start+0xffffc800>
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//! 20000008: 80004137 lui sp,0x80004
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//! ```
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//!
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//! # Symbol interfaces
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//!
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//! This crate makes heavy use of symbols, linker sections and linker scripts to
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//! provide most of its functionality. Below are described the main symbol
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//! interfaces.
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//!
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//! ## `memory.x`
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//!
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//! This file supplies the information about the device to the linker.
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//!
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//! ### `MEMORY`
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//!
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//! The main information that this file must provide is the memory layout of
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//! the device in the form of the `MEMORY` command. The command is documented
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//! [here][2], but at a minimum you'll want to create at least one memory region.
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//!
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//! [2]: https://sourceware.org/binutils/docs/ld/MEMORY.html
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//!
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//! To support different relocation models (RAM-only, FLASH+RAM) multiple regions are used:
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//!
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//! - `REGION_TEXT` - for `.init`, `.trap` and `.text` sections
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//! - `REGION_RODATA` - for `.rodata` section and storing initial values for `.data` section
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//! - `REGION_DATA` - for `.data` section
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//! - `REGION_BSS` - for `.bss` section
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//! - `REGION_HEAP` - for the heap area
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//! - `REGION_STACK` - for hart stacks
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//!
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//! Specific aliases for these regions must be defined in `memory.x` file (see example below).
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//!
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//! ### `_stext`
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//!
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//! This symbol provides the loading address of `.text` section. This value can be changed
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//! to override the loading address of the firmware (for example, in case of bootloader present).
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//!
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//! If omitted this symbol value will default to `ORIGIN(REGION_TEXT)`.
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//!
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//! ### `_stack_start`
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//!
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//! This symbol provides the address at which the call stack will be allocated.
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//! The call stack grows downwards so this address is usually set to the highest
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//! valid RAM address plus one (this *is* an invalid address but the processor
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//! will decrement the stack pointer *before* using its value as an address).
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//!
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//! In case of multiple harts present, this address defines the initial stack pointer for hart 0.
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//! Stack pointer for hart `N` is calculated as `_stack_start - N * _hart_stack_size`.
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//!
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//! If omitted this symbol value will default to `ORIGIN(REGION_STACK) + LENGTH(REGION_STACK)`.
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//!
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//! #### Example
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//!
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//! Allocating the call stack on a different RAM region.
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//!
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//! ``` text
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//! MEMORY
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//! {
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//! L2_LIM : ORIGIN = 0x08000000, LENGTH = 1M
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//! RAM : ORIGIN = 0x80000000, LENGTH = 16K
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//! FLASH : ORIGIN = 0x20000000, LENGTH = 16M
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//! }
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//!
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//! REGION_ALIAS("REGION_TEXT", FLASH);
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//! REGION_ALIAS("REGION_RODATA", FLASH);
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//! REGION_ALIAS("REGION_DATA", RAM);
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//! REGION_ALIAS("REGION_BSS", RAM);
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//! REGION_ALIAS("REGION_HEAP", RAM);
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//! REGION_ALIAS("REGION_STACK", L2_LIM);
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//!
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//! _stack_start = ORIGIN(L2_LIM) + LENGTH(L2_LIM);
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//! ```
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//!
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//! ### `_max_hart_id`
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//!
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//! This symbol defines the maximum hart id suppoted. All harts with id
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//! greater than `_max_hart_id` will be redirected to `abort()`.
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//!
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//! This symbol is supposed to be redefined in platform support crates for
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//! multi-core targets.
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//!
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//! If omitted this symbol value will default to 0 (single core).
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//!
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//! ### `_hart_stack_size`
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//!
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//! This symbol defines stack area size for *one* hart.
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//!
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//! If omitted this symbol value will default to 2K.
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//!
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//! ### `_heap_size`
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//!
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//! This symbol provides the size of a heap region. The default value is 0. You can set `_heap_size`
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//! to a non-zero value if you are planning to use heap allocations.
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//!
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//! ### `_sheap`
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//!
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//! This symbol is located in RAM right after the `.bss` and `.data` sections.
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//! You can use the address of this symbol as the start address of a heap
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//! region. This symbol is 4 byte aligned so that address will be a multiple of 4.
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//!
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//! #### Example
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//!
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//! ``` no_run
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//! extern crate some_allocator;
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//!
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//! extern "C" {
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//! static _sheap: u8;
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//! static _heap_size: u8;
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//! }
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//!
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//! fn main() {
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//! unsafe {
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//! let heap_bottom = &_sheap as *const u8 as usize;
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//! let heap_size = &_heap_size as *const u8 as usize;
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//! some_allocator::initialize(heap_bottom, heap_size);
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//! }
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//! }
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//! ```
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//!
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//! ### `_mp_hook`
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//!
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//! This function is called from all the harts and must return true only for one hart,
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//! which will perform memory initialization. For other harts it must return false
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//! and implement wake-up in platform-dependent way (e.g. after waiting for a user interrupt).
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//!
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//! This function can be redefined in the following way:
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//!
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//! ``` no_run
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//! #[export_name = "_mp_hook"]
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//! pub extern "Rust" fn mp_hook() -> bool {
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//! // ...
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//! }
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//! ```
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//!
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//! Default implementation of this function wakes hart 0 and busy-loops all the other harts.
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// NOTE: Adapted from cortex-m/src/lib.rs
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#![no_std]
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#![deny(missing_docs)]
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#![deny(warnings)]
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extern crate xous_riscv;
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extern crate riscv_rt_macros as macros;
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extern crate r0;
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pub use macros::{entry, pre_init};
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use xous_riscv::register::mstatus;
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#[export_name = "error: riscv-rt appears more than once in the dependency graph"]
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#[doc(hidden)]
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pub static __ONCE__: () = ();
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extern "C" {
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// Boundaries of the .bss section
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static mut _ebss: u32;
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static mut _sbss: u32;
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// Boundaries of the .data section
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static mut _edata: u32;
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static mut _sdata: u32;
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// Initial values of the .data section (stored in Flash)
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static _sidata: u32;
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}
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/// Rust entry point (_start_rust)
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///
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/// Zeros bss section, initializes data section and calls main. This function
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/// never returns.
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#[link_section = ".init.rust"]
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#[export_name = "_start_rust"]
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pub unsafe extern "C" fn start_rust() -> ! {
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extern "Rust" {
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// This symbol will be provided by the kernel
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fn xous_main() -> !;
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// This symbol will be provided by the user via `#[pre_init]`
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fn __pre_init();
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fn _mp_hook() -> bool;
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}
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if _mp_hook() {
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__pre_init();
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r0::zero_bss(&mut _sbss, &mut _ebss);
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r0::init_data(&mut _sdata, &mut _edata, &_sidata);
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}
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xous_main();
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}
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/// Trap entry point rust (_start_trap_rust)
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///
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/// mcause is read to determine the cause of the trap. XLEN-1 bit indicates
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/// if it's an interrupt or an exception. The result is converted to an element
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/// of the Interrupt or Exception enum and passed to handle_interrupt or
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/// handle_exception.
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#[link_section = ".trap.rust"]
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#[export_name = "_start_trap_rust"]
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pub extern "C" fn start_trap_rust() {
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extern "C" {
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fn trap_handler();
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}
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unsafe {
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// dispatch trap to handler
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trap_handler();
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// mstatus, remain in M-mode after mret
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mstatus::set_mpp(mstatus::MPP::Machine);
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}
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}
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#[doc(hidden)]
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#[no_mangle]
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pub fn default_trap_handler() {}
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#[doc(hidden)]
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#[no_mangle]
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pub unsafe extern "Rust" fn default_pre_init() {}
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#[doc(hidden)]
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#[no_mangle]
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pub extern "Rust" fn default_mp_hook() -> bool {
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use xous_riscv::register::mhartid;
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match mhartid::read() {
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0 => true,
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_ => loop {
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unsafe { xous_riscv::asm::wfi() }
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},
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}
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}
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