path: root/src/devices/memory_device.rs



use bedrock_core::*;

type Page = [u8; 256];

macro_rules! fn_read_head {
    ($fn_name:ident($offset:ident, $address:ident)) => {
        pub fn $fn_name(&mut self) -> u8 {
            let page_i = (self.$offset + (self.$address / 256)) as usize;
            let byte_i = (self.$address % 256) as usize;
            self.$address = self.$address.wrapping_add(1);
            match self.pages.get(page_i) {
                Some(page) => page[byte_i],
                None => 0,
            }
        }
    };
}

macro_rules! fn_write_head {
    ($fn_name:ident($offset:ident, $address:ident)) => {
        pub fn $fn_name(&mut self, byte: u8) {
            let page_i = (self.$offset + (self.$address / 256)) as usize;
            let byte_i = (self.$address % 256) as usize;
            self.$address = self.$address.wrapping_add(1);
            match self.pages.get_mut(page_i) {
                Some(page) => page[byte_i] = byte,
                None => if page_i < self.provisioned {
                    self.pages.resize(page_i + 1, [0; 256]);
                    self.pages[page_i][byte_i] = byte;
                }
            }
        }
    };
}


pub struct MemoryDevice {
    pub limit: u16,          // maximum provisionable number of pages
    pub requested: u16,      // number of pages requested by program
    pub provisioned: usize,  // number of pages provisioned for use
    pub pages: Vec<Page>,    // all allocated pages

    pub offset_1: u16,
    pub address_1: u16,
    pub offset_2: u16,
    pub address_2: u16,

    pub copy_length: u16,
}

impl MemoryDevice {
    pub fn new() -> Self {
        Self {
            limit: 0,
            requested: 0,
            provisioned: 0,
            pages: Vec::new(),

            offset_1: 0,
            address_1: 0,
            offset_2: 0,
            address_2: 0,

            copy_length: 0,
        }
    }

    fn_read_head! { read_head_1( offset_1, address_1) }
    fn_read_head! { read_head_2( offset_2, address_2) }
    fn_write_head!{ write_head_1(offset_1, address_1) }
    fn_write_head!{ write_head_2(offset_2, address_2) }

    pub fn provision(&mut self) {
        self.provisioned = std::cmp::min(self.requested, self.limit) as usize;
        // Defer allocation of new pages.
        self.pages.truncate(self.provisioned as usize);
    }

    pub fn copy(&mut self) {
        let src  = self.offset_2 as usize;
        let dest = self.offset_1 as usize;
        let count = self.copy_length as usize;

        // Pre-allocate destination pages as needed.
        let pages_needed = std::cmp::min(dest + count, self.provisioned);
        if pages_needed > self.pages.len() {
            self.pages.resize(pages_needed, [0; 256]);
        }

        for i in 0..count {
            let src_page = match self.pages.get(src + i) {
                Some(src_page) => src_page.to_owned(),
                None => [0; 256],
            };
            match self.pages.get_mut(dest + i) {
                Some(dest) => *dest = src_page,
                None => break,
            };
        }
    }
}

impl Device for MemoryDevice {
    fn read(&mut self, port: u8) -> u8 {
        match port {
            0x0 => self.read_head_1(),
            0x1 => self.read_head_1(),
            0x2 => read_h!(self.offset_1),
            0x3 => read_l!(self.offset_1),
            0x4 => read_h!(self.address_1),
            0x5 => read_l!(self.address_1),
            0x6 => read_h!(self.provisioned),
            0x7 => read_l!(self.provisioned),
            0x8 => self.read_head_2(),
            0x9 => self.read_head_2(),
            0xa => read_h!(self.offset_2),
            0xb => read_l!(self.offset_2),
            0xc => read_h!(self.address_2),
            0xd => read_l!(self.address_2),
            0xe => 0x00,
            0xf => 0x00,
            _ => unreachable!(),
        }
    }

    fn write(&mut self, port: u8, value: u8) -> Option<Signal> {
        match port {
            0x0 => self.write_head_1(value),
            0x1 => self.write_head_1(value),
            0x2 => write_h!(self.offset_1, value),
            0x3 => write_l!(self.offset_1, value),
            0x4 => write_h!(self.address_1, value),
            0x5 => write_l!(self.address_1, value),
            0x6 => write_h!(self.requested, value),
            0x7 => { write_l!(self.requested, value); self.provision(); },
            0x8 => self.write_head_2(value),
            0x9 => self.write_head_2(value),
            0xa => write_h!(self.offset_2, value),
            0xb => write_l!(self.offset_2, value),
            0xc => write_h!(self.address_2, value),
            0xd => write_l!(self.address_2, value),
            0xe => write_h!(self.copy_length, value),
            0xf => { write_l!(self.copy_length, value); self.copy(); },
            _ => unreachable!(),
        };
        return None;
    }

    fn wake(&mut self) -> bool {
        false
    }
}
use bedrock_core::*;

type Page = [u8; 256];

macro_rules! fn_read_head {
    ($fn_name:ident($offset:ident, $address:ident)) => {
        pub fn $fn_name(&mut self) -> u8 {
            let page_i = (self.$offset + (self.$address / 256)) as usize;
            let byte_i = (self.$address % 256) as usize;
            self.$address = self.$address.wrapping_add(1);
            match self.pages.get(page_i) {
                Some(page) => page[byte_i],
                None => 0,
            }
        }
    };
}

macro_rules! fn_write_head {
    ($fn_name:ident($offset:ident, $address:ident)) => {
        pub fn $fn_name(&mut self, byte: u8) {
            let page_i = (self.$offset + (self.$address / 256)) as usize;
            let byte_i = (self.$address % 256) as usize;
            self.$address = self.$address.wrapping_add(1);
            match self.pages.get_mut(page_i) {
                Some(page) => page[byte_i] = byte,
                None => if page_i < self.provisioned {
                    self.pages.resize(page_i + 1, [0; 256]);
                    self.pages[page_i][byte_i] = byte;
                }
            }
        }
    };
}


pub struct MemoryDevice {
    pub limit: u16,          // maximum provisionable number of pages
    pub requested: u16,      // number of pages requested by program
    pub provisioned: usize,  // number of pages provisioned for use
    pub pages: Vec<Page>,    // all allocated pages

    pub offset_1: u16,
    pub address_1: u16,
    pub offset_2: u16,
    pub address_2: u16,

    pub copy_length: u16,
}

impl MemoryDevice {
    pub fn new() -> Self {
        Self {
            limit: 0,
            requested: 0,
            provisioned: 0,
            pages: Vec::new(),

            offset_1: 0,
            address_1: 0,
            offset_2: 0,
            address_2: 0,

            copy_length: 0,
        }
    }

    fn_read_head! { read_head_1( offset_1, address_1) }
    fn_read_head! { read_head_2( offset_2, address_2) }
    fn_write_head!{ write_head_1(offset_1, address_1) }
    fn_write_head!{ write_head_2(offset_2, address_2) }

    pub fn provision(&mut self) {
        self.provisioned = std::cmp::min(self.requested, self.limit) as usize;
        // Defer allocation of new pages.
        self.pages.truncate(self.provisioned as usize);
    }

    pub fn copy(&mut self) {
        let src  = self.offset_2 as usize;
        let dest = self.offset_1 as usize;
        let count = self.copy_length as usize;

        // Pre-allocate destination pages as needed.
        let pages_needed = std::cmp::min(dest + count, self.provisioned);
        if pages_needed > self.pages.len() {
            self.pages.resize(pages_needed, [0; 256]);
        }

        for i in 0..count {
            let src_page = match self.pages.get(src + i) {
                Some(src_page) => src_page.to_owned(),
                None => [0; 256],
            };
            match self.pages.get_mut(dest + i) {
                Some(dest) => *dest = src_page,
                None => break,
            };
        }
    }
}

impl Device for MemoryDevice {
    fn read(&mut self, port: u8) -> u8 {
        match port {
            0x0 => self.read_head_1(),
            0x1 => self.read_head_1(),
            0x2 => read_h!(self.offset_1),
            0x3 => read_l!(self.offset_1),
            0x4 => read_h!(self.address_1),
            0x5 => read_l!(self.address_1),
            0x6 => read_h!(self.provisioned),
            0x7 => read_l!(self.provisioned),
            0x8 => self.read_head_2(),
            0x9 => self.read_head_2(),
            0xa => read_h!(self.offset_2),
            0xb => read_l!(self.offset_2),
            0xc => read_h!(self.address_2),
            0xd => read_l!(self.address_2),
            0xe => 0x00,
            0xf => 0x00,
            _ => unreachable!(),
        }
    }

    fn write(&mut self, port: u8, value: u8) -> Option<Signal> {
        match port {
            0x0 => self.write_head_1(value),
            0x1 => self.write_head_1(value),
            0x2 => write_h!(self.offset_1, value),
            0x3 => write_l!(self.offset_1, value),
            0x4 => write_h!(self.address_1, value),
            0x5 => write_l!(self.address_1, value),
            0x6 => write_h!(self.requested, value),
            0x7 => { write_l!(self.requested, value); self.provision(); },
            0x8 => self.write_head_2(value),
            0x9 => self.write_head_2(value),
            0xa => write_h!(self.offset_2, value),
            0xb => write_l!(self.offset_2, value),
            0xc => write_h!(self.address_2, value),
            0xd => write_l!(self.address_2, value),
            0xe => write_h!(self.copy_length, value),
            0xf => { write_l!(self.copy_length, value); self.copy(); },
            _ => unreachable!(),
        };
        return None;
    }

    fn wake(&mut self) -> bool {
        false
    }
}