burritos/src/simulator/loader.rs

use crate::Machine;
use std::fmt::Error;
use std::fs;
use std::io::Read;

/// load a 32-bits binary file into the machine
/// 
/// ### Parameters
/// 
/// - **path** path of the file to load
/// - **machine** the machine where the bin file will be loaded
/// - **start_index** at which index of machine memory you want to start to load the program
/// 
/// Returns in a Result any io error
pub fn load(path: &str, machine: &mut Machine, start_index: usize) -> Result<(), std::io::Error> {
    let mut file = fs::File::open(path)?;
    let mut instructions: Vec<u32> = Default::default();
    loop {
        let mut buf: [u8; 4] = [0; 4];
        let res = file.read(&mut buf)?;
        if res == 0 {
            break; // eof
        } else {
            instructions.push(u32::from_le_bytes(buf));
        }
    }
    for i in 0..instructions.len() {
        machine.write_memory(4, 4 * i + start_index, instructions[i] as u64);
    }
    // #[cfg(debug_assertions)]
    // println!("{:04x?}", instructions); // only print loaded program in debug build
    Ok(())
}

pub struct ElfHeader {
    pub endianess: bool,
    pub is_32bits: bool,
    pub version: u8,
    pub sys_v_abi: bool,
    pub is_riscv_target: bool,
    pub entrypoint: u64,
    pub elf_header_size: u16,
    pub program_header_location: u64,
    pub program_header_entries: u16,
    pub program_header_size: u16,
    pub section_header_location: u64,
    pub section_header_entries: u16,
    pub section_header_size: u16,
}

impl ElfHeader {
    
    /// return true if the 4 first bytes constitude the elf magic number
    fn is_elf(instructions: &Vec<u8>) -> bool {
        instructions.get(0..4) == Option::Some(&[0x7f, 0x45, 0x4c, 0x46])
    }

    /// return true if big endian, false otherwise
    fn check_endianess(instructions: &Vec<u8>) -> bool {
        instructions.get(5) == Option::Some(&2)
    }

    /// return true if file is 32 bits, false if 64 bits
    fn is_32bits(instructions: &Vec<u8>) -> bool {
        instructions.get(4) == Option::Some(&1)
    }

    /// return the version of the elf file (should be 1)
    /// Can be None if the file is smaller than 7 bytes -> the file is invalid
    fn get_version(instructions: &Vec<u8>) -> Option<u8> {
        instructions.get(6).copied() // work as primitives implements Copy
    }

    /// return true if target abi of the binary file is System V, false otherwise
    fn is_system_v_elf(instructions: &Vec<u8>) -> bool {
        instructions.get(7) == Option::Some(&0)
    }

    /// return true if specified target instruction set architecture is RISCV
    fn is_riscv_isa(instructions: &Vec<u8>) -> bool {
        Self::get_u16_value(instructions, 0x12) == Option::Some(0xf3)
    }

    /// memory address of the entry point from where the process starts its execution
    fn get_entrypoint(instructions: &Vec<u8>, is_32bits: bool) -> Option<u64> {
        if is_32bits {
            Self::get_address_point(instructions, 0x18, true)
        } else {
            Self::get_address_point(instructions, 0x18, false)
        }
    }

    /// Memory address of the start of the program header table
    fn get_program_header_table_location(instructions: &Vec<u8>, is_32bits: bool) -> Option<u64> {
        if is_32bits {
            Self::get_address_point(instructions, 0x1c, true)
        } else {
            Self::get_address_point(instructions, 0x20, false)
        }
    }

    /// Memory address of the start of the section header table 
    fn get_section_header_table_location(instructions: &Vec<u8>, is_32bits: bool) -> Option<u64> {
        if is_32bits {
            Self::get_address_point(instructions, 0x20, true)
        } else {
            Self::get_address_point(instructions, 0x28, false)
        }
    }

    /// Return the size of the header, normally, 0x40 for 64 bits bin and 0x34 for 32 bits
    fn get_elf_header_size(instructions: &Vec<u8>, is_32bits: bool) -> Option<u16> {
        let address = if is_32bits { 0x28 } else { 0x34 };
        Self::get_u16_value(instructions, address)
    }

    /// return the size of a program header table entry
    fn get_program_header_size(instructions: &Vec<u8>, is_32bits: bool) -> Option<u16> {
        let address = if is_32bits { 0x2a } else { 0x36 };
        Self::get_u16_value(instructions, address)
    }

    /// return the number of entries in the program header
    fn get_number_entries_program_header(instructions: &Vec<u8>, is_32bits: bool) -> Option<u16> {
        let address = if is_32bits { 0x2c } else { 0x38 };
        Self::get_u16_value(instructions, address)
    }

    /// Return the size of a section header table entry
    fn get_section_header_size(instructions: &Vec<u8>, is_32bits: bool) -> Option<u16> {
        let address = if is_32bits { 0x2e } else { 0x3a };
        Self::get_u16_value(instructions, address)
    }

    /// Return the number of entries in the section header
    fn get_section_header_num_entries(instructions: &Vec<u8>, is_32bits: bool) -> Option<u16> {
        let address = if is_32bits { 0x30 } else { 0x3c };
        Self::get_u16_value(instructions, address)
    }

    /// return the memory address of something stored at address
    /// Can return None if the file is smaller than adress + 3 (or 7 if 64 bits), in this case, the elf header is incorrect
    fn get_address_point(instructions: &Vec<u8>, address: usize, is_32bits: bool) -> Option<u64> {
        if is_32bits {
            let mut bytes: [u8; 4] = [0; 4];
            bytes[0] = instructions.get(address).copied()?;
            bytes[1] = instructions.get(address + 1).copied()?;
            bytes[2] = instructions.get(address + 2).copied()?;
            bytes[3] = instructions.get(address + 3).copied()?;
            Option::Some(u32::from_le_bytes(bytes) as u64)
        } else {
            let mut bytes: [u8; 8] = [0; 8];
            bytes[0] = instructions.get(address).copied()?;
            bytes[1] = instructions.get(address + 1).copied()?;
            bytes[2] = instructions.get(address + 2).copied()?;
            bytes[3] = instructions.get(address + 3).copied()?;
            bytes[4] = instructions.get(address + 4).copied()?;
            bytes[5] = instructions.get(address + 5).copied()?;
            bytes[6] = instructions.get(address + 6).copied()?;
            bytes[7] = instructions.get(address + 7).copied()?;
            Option::Some(u64::from_le_bytes(bytes))
        }
    }

    /// Return a u16 value, usually for the size or the number of entries inside a header
    fn get_u16_value(instructions: &Vec<u8>, address: usize) -> Option<u16> {
        let mut bytes: [u8; 2] = [0; 2];
        bytes[0] = instructions.get(address).copied()?;
        bytes[1] = instructions.get(address + 1).copied()?;
        Option::Some(u16::from_le_bytes(bytes))
    }
    
}

impl TryFrom<&Vec<u8>> for ElfHeader {
    type Error = ();

    fn try_from(instructions: &Vec<u8>) -> Result<Self, Self::Error> {
        if Self::is_elf(instructions) {
            let format = Self::is_32bits(instructions);
            let endianess = Self::check_endianess(instructions);
            let version = Self::get_version(instructions).ok_or(())?;
            let is_sys_v_abi = Self::is_system_v_elf(instructions);
            let is_rv_target = Self::is_riscv_isa(instructions);
            let entrypoint = Self::get_entrypoint(instructions, format).ok_or(())?;
            let elf_header_size = Self::get_elf_header_size(instructions, format).ok_or(())?;
            let program_header_location = Self::get_program_header_table_location(instructions, format).ok_or(())?;
            let program_header_entries = Self::get_number_entries_program_header(instructions, format).ok_or(())? ;
            let program_header_size = Self::get_program_header_size(instructions, format).ok_or(())?;
            let section_header_location = Self::get_section_header_table_location(instructions, format).ok_or(())?;
            let section_header_entries = Self::get_section_header_num_entries(instructions, format).ok_or(())?;
            let section_header_size = Self::get_section_header_size(instructions, format).ok_or(())?;
            Ok(ElfHeader { 
                endianess, 
                is_32bits: format,
                version,
                sys_v_abi: is_sys_v_abi,
                is_riscv_target: is_rv_target,
                entrypoint,
                elf_header_size,
                program_header_location,
                program_header_entries,
                program_header_size,
                section_header_location,
                section_header_entries,
                section_header_size
            })
        } else {
            Err(())
        }
    }
}

pub struct SectionHeader {
    pub name_offset: u32,
    pub header_type: u32,
    pub attribute: u64,
    pub virt_addr: u64,
    pub image_offset: u64,
    pub section_size: u64,
    pub section_index: u32,
    pub section_info: u32,
    pub required_align: u64,
    pub entry_size: u64
}

impl TryFrom<(&Vec<u8>, u64)> for SectionHeader {
    type Error = ();

    fn try_from(value: (&Vec<u8>, u64)) -> Result<Self, Self::Error> {
        todo!()
    }
}

pub struct Loader {
    bytes: Vec<u8>,
    pub elf_header: ElfHeader,
    pub sections: Vec<SectionHeader>
}

pub enum LoaderError {
    IOError(std::io::Error),
    ParsingError
}

impl Loader {

    pub fn load(path: &str, machine: &mut Machine, start_index: usize) -> Result<Self, LoaderError> {
        let file = fs::File::open(path);
        match file {
            Ok(mut file) => {
                let mut instructions: Vec<u8> = Default::default();
                loop {
                    let mut buf: [u8; 1] = [0; 1];
                    let res = file.read(&mut buf);
                    match res {
                        Ok(res) => {
                            if res == 0 {
                                break; // eof
                            } else {
                                instructions.push(buf[0]);
                            }
                        },
                        Err(err) => {
                            return Err(LoaderError::IOError(err))
                        }
                    }
                    
                }
                let elf_header = match ElfHeader::try_from(&instructions) {
                    Ok(header) => {
                        header
                    },
                    Err(_) => {
                        return Err(LoaderError::ParsingError);
                    }
                };
                let section_header = match Self::parse_section_header(&instructions, elf_header.is_32bits, elf_header.section_header_location, elf_header.section_header_entries, elf_header.section_header_size) {
                    Ok(header) => {
                        header
                    },
                    Err(_) => {
                        return Err(LoaderError::ParsingError);
                    }
                };
                // #[cfg(debug_assertions)]
                // println!("{:04x?}", instructions); // only print loaded program in debug build
                return Ok(Self { bytes: instructions, elf_header, sections: section_header });
            },
            Err(err) => {
                return Err(LoaderError::IOError(err));
            }
        };
    }

    fn parse_section_header(instructions: &Vec<u8>, is_32bits: bool, header_location: u64, num_of_entries: u16, entry_size: u16) -> Result<Vec<SectionHeader>, ()> {
        let mut sections: Vec<SectionHeader> = Default::default();
        for i in 0..num_of_entries as u64 {
            sections.push(Self::parse_section_entry(instructions, is_32bits, header_location + i * entry_size as u64)?);
        }
        Ok(sections)
    }

    fn parse_section_entry(instructions: &Vec<u8>, is_32bits: bool, location: u64) -> Result<SectionHeader, ()> {
        SectionHeader::try_from((instructions, location))
    }


}

#[cfg(test)]
mod test {
    use crate::simulator::{loader::Loader, machine::Machine};


    #[test]
    fn test_parse_elf() {
        // let mut machine = Machine::init_machine();
        // let loader = Loader::load("./test/riscv_instructions/simple_arithmetics/unsigned_addition", &mut machine, 0).expect("IO Error");
        // assert_eq!(true, loader.is_elf());
        // assert_eq!(false, loader.is_32bits());
        // assert_eq!(false, loader.check_endianess());
        // assert_eq!(true, loader.is_system_v_elf());
        // assert_eq!(true, loader.is_riscv_isa());
        // assert_eq!(Option::Some(1), loader.get_version());
        // assert_eq!(Option::Some(0x4000), loader.get_entrypoint(false));
        // assert_eq!(Option::Some(64), loader.get_elf_header_size(false));
        // assert_eq!(Option::Some(64), loader.get_program_header_table_location(false));
        // assert_eq!(Option::Some(18984), loader.get_section_header_table_location(false));
        // assert_eq!(Option::Some(56), loader.get_program_header_size(false));
        // assert_eq!(Option::Some(64), loader.get_section_header_size(false));
        // assert_eq!(Option::Some(4), loader.get_number_entries_program_header(false));
        // assert_eq!(Option::Some(9), loader.get_section_header_num_entries(false));
    }

}