Crates.io | lib_rv32 |
lib.rs | lib_rv32 |
version | 0.1.1 |
source | src |
created_at | 2021-08-05 17:42:40.059805 |
updated_at | 2021-08-05 21:57:50.160732 |
description | A library and CLI tool for emulating, testing, and learning RISC-V. |
homepage | https://github.com/trmckay/lib-rv32 |
repository | https://github.com/trmckay/lib-rv32 |
max_upload_size | |
id | 432103 |
size | 56,563 |
Rust library for emulating 32-bit RISC-V
This library can execute instructions against any memory and register file that implements
the required primitives in the traits lib_rv32::traits::{Memory, RegisterFile}
. This is to
encourage usage with whatever frontend you desire.
However, reference implementations are provided in lib_rv32::mcu
. The library provides
functions to read from the memory, registers, and step a single instruction. Since, the
user decides when to call these functions, these will probably fit most use-cases.
my_app.rs
:
use std::path::Path;
use lib_rv32::mcu::*;
use lib_rv32::exec_one;
fn main() {
let mut mcu: Mcu = Mcu::new(1024 * 64);
mcu.mem
.program_from_file(&Path::from("./prog.bin"))
.expect("Could not program MCU.");
loop {
exec_one(&mut mcu.pc, &mut mcu.mem, &mut mcu.rf).unwrap();
}
}
The CLI is one example of how the core library can be used in an application. The primary use of the CLI is tracing execution of RISC-V programs and making assertions about their behavior. It currently only supports simple binary memory images (not ELF binaries).
USAGE:
lrv-cli [FLAGS] [OPTIONS] <binary>
FLAGS:
-h, --help Prints help information
-V, --version Prints version information
-v, --verbose Enable verbose logging
OPTIONS:
-a, --assertions <ASSERTIONS> A JSON formatted set of assertions.
-m, --mem <MEM_SIZE> Set the size of the MCU memory (default 64 KB).
-s, --stop <STOP_PC> Set the program counter at which to stop emulation.
ARGS:
<binary> RISC-V binary to execute
Enter assertions into a JSON file (note: all numbers are strings to allow for hex or decimal radices).
assert.json
:
{
"registers": {
"x0": "0x0",
"a0": "20"
},
"memory": {
"0x0000": "0x00010117"
}
}
Then run:
lrv-cli -v ./prog.bin -s 24 -a assert.json
This will execute prog.bin
, stop at the PC value 0x24, and then make the assertions from assert.json
.
The program will trace the execution instruction-by-instruction:
[0000] 00010117 | auipc sp, 0x10 | sp <- 0x10000 (65536);
[0004] fe010113 | addi sp, sp, -32 | sp <- 0xffe0 (65504);
[0008] 00400513 | addi a0, zero, 4 | a0 <- 0x4 (4);
[000c] 00500593 | addi a1, zero, 5 | a1 <- 0x5 (5);
[0010] 00000097 | auipc ra, 0x0 | ra <- 0x10 (16);
[0014] 018080e7 | jalr ra, (24)ra | ra <- 0x18 (24); pc <- 0x28;
...
When complete, it will summarize results:
...
[001c] f0028293 | addi t0, t0, -256 | t0 <- 0xf00 (3840);
[0020] 00a2a023 | sw a0, 0(t0) | (word *)0x00000f00 <- 0x14 (20);
Reached stop-PC.
a0 == 20
*0x00000000 == 65815
This project has a very flexible testing system.
Unit-tests are provided wherever appropriate.
Additionally, to test the whole system, test programs can be added to tests/programs
.
A test is simply a directory containing .c
and .s
source files and a test_case.json
consisting of assertions about the state of the MCU after the program is complete.
During testing, Cargo will for each test:
If a test fails, it will describe the error that caused the crash or the assertion that failed and print an object dump of the compiled test binary:
...
[001c] f0028293 | addi t0, t0, -256 | t0 <- 0xf00 (3840);
[0020] 00a2a023 | sw a0, 0(t0) | (word *)0x00000f00 <- 0x14 (20);
Stopping because the stop PC 0x24 was reached.
Failed test: tests/programs/mul@0x00000024: Register assertion failed: (x10=0x00000014) != 0x00000018.
prog.elf: file format elf32-littleriscv
Disassembly of section .text.init:
00000000 <start>:
0: 00010117 auipc sp,0x10
4: fe010113 addi sp,sp,-32 # ffe0 <__global_pointer$+0xf75c>
8: 00400513 li a0,4
c: 00500593 li a1,5
...
Tests are run in CI, but can be run locally provided your system has riscv(32|64)-unknown-elf-gcc
.