use std::rc::Rc; use std::cell::RefCell; use crate::error::Error; use crate::system::System; pub const MAX_READ: usize = 4; /// The time in nanoseconds that have elapsed since the start of the simulation pub type Clock = u64; /// The time in nanoseconds until the `step()` method should be called again pub type ClockElapsed = u64; /// A universal memory address used by the Addressable trait pub type Address = u64; /// A device that can change state over time. The `step()` method will be called /// by the containing `System` when the system clock advances. If an error occurs /// with any device, the `on_error()` method will be called to display any state /// information that might be helpful for debugging. pub trait Steppable { fn step(&mut self, system: &System) -> Result; fn on_error(&mut self, _system: &System) { } } /// A device that can receive an interrupt. The `interrupt_state_change()` method /// will be called whenever an interrupt signal changes goes high or low. pub trait Interruptable { //fn interrupt_state_change(&mut self, state: bool, priority: u8, number: u8) -> Result<(), Error>; } /// A device that can debugged using the built-in debugger pub trait Debuggable { fn add_breakpoint(&mut self, addr: Address); fn remove_breakpoint(&mut self, addr: Address); fn print_current_step(&mut self, system: &System) -> Result<(), Error>; fn print_disassembly(&mut self, addr: Address, count: usize); fn execute_command(&mut self, system: &System, args: &[&str]) -> Result; } /// A device that can be addressed to read data from or write data to the device. pub trait Addressable { fn len(&self) -> usize; fn read(&mut self, addr: Address, data: &mut [u8]) -> Result<(), Error>; fn write(&mut self, addr: Address, data: &[u8]) -> Result<(), Error>; fn read_u8(&mut self, addr: Address) -> Result { let mut data = [0; 1]; self.read(addr, &mut data)?; Ok(data[0]) } fn read_beu16(&mut self, addr: Address) -> Result { let mut data = [0; 2]; self.read(addr, &mut data)?; Ok(read_beu16(&data)) } fn read_beu32(&mut self, addr: Address) -> Result { let mut data = [0; 4]; self.read(addr, &mut data)?; Ok(read_beu32(&data)) } fn write_u8(&mut self, addr: Address, value: u8) -> Result<(), Error> { let data = [value]; self.write(addr, &data) } fn write_beu16(&mut self, addr: Address, value: u16) -> Result<(), Error> { let data = write_beu16(value); self.write(addr, &data) } fn write_beu32(&mut self, addr: Address, value: u32) -> Result<(), Error> { let data = write_beu32(value); self.write(addr, &data) } } #[inline(always)] pub fn read_beu16(data: &[u8]) -> u16 { (data[0] as u16) << 8 | (data[1] as u16) } #[inline(always)] pub fn read_beu32(data: &[u8]) -> u32 { (data[0] as u32) << 24 | (data[1] as u32) << 16 | (data[2] as u32) << 8 | (data[3] as u32) } #[inline(always)] pub fn write_beu16(value: u16) -> [u8; 2] { [ (value >> 8) as u8, value as u8, ] } #[inline(always)] pub fn write_beu32(value: u32) -> [u8; 4] { [ (value >> 24) as u8, (value >> 16) as u8, (value >> 8) as u8, value as u8, ] } pub trait Transmutable { fn as_steppable(&mut self) -> Option<&mut dyn Steppable> { None } fn as_addressable(&mut self) -> Option<&mut dyn Addressable> { None } fn as_interruptable(&mut self) -> Option<&mut dyn Interruptable> { None } fn as_debuggable(&mut self) -> Option<&mut dyn Debuggable> { None } } pub type TransmutableBox = Rc>>; pub fn wrap_transmutable(value: T) -> TransmutableBox { Rc::new(RefCell::new(Box::new(value))) }